Diversity of cells and signals in the cardiovascular system

Grandi, Eleonora; Navedo, Manuel F.; Saucerman, Jeffrey J.; Bers, Donald M.; Chiamvimonvat, Nipavan; Dixon, Rose E.; Dobrev, Dobromir; Gomez, Ana M.; Harraz, Osama F.; Hegyi, Bence; Jones, David K.; Krogh-Madsen, Trine; Murfee, Walter Lee; Nystoriak, Matthew A.; Posnack, Nikki G.; Ripplinger, Crystal M.; Veeraraghavan, Rengasayee; Weinberg, Seth

Diversity of cells and signals in the cardiovascular system

dc.contributor.author	Grandi, Eleonora
dc.contributor.author	Navedo, Manuel F.
dc.contributor.author	Saucerman, Jeffrey J.
dc.contributor.author	Bers, Donald M.
dc.contributor.author	Chiamvimonvat, Nipavan
dc.contributor.author	Dixon, Rose E.
dc.contributor.author	Dobrev, Dobromir
dc.contributor.author	Gomez, Ana M.
dc.contributor.author	Harraz, Osama F.
dc.contributor.author	Hegyi, Bence
dc.contributor.author	Jones, David K.
dc.contributor.author	Krogh-Madsen, Trine
dc.contributor.author	Murfee, Walter Lee
dc.contributor.author	Nystoriak, Matthew A.
dc.contributor.author	Posnack, Nikki G.
dc.contributor.author	Ripplinger, Crystal M.
dc.contributor.author	Veeraraghavan, Rengasayee
dc.contributor.author	Weinberg, Seth
dc.date.accessioned	2023-07-14T13:58:22Z
dc.date.available	2024-08-14 09:58:20	en
dc.date.available	2023-07-14T13:58:22Z
dc.date.issued	2023-07
dc.identifier.citation	Grandi, Eleonora; Navedo, Manuel F.; Saucerman, Jeffrey J.; Bers, Donald M.; Chiamvimonvat, Nipavan; Dixon, Rose E.; Dobrev, Dobromir; Gomez, Ana M.; Harraz, Osama F.; Hegyi, Bence; Jones, David K.; Krogh-Madsen, Trine ; Murfee, Walter Lee; Nystoriak, Matthew A.; Posnack, Nikki G.; Ripplinger, Crystal M.; Veeraraghavan, Rengasayee; Weinberg, Seth (2023). "Diversity of cells and signals in the cardiovascular system." The Journal of Physiology 601(13): 2547-2592.
dc.identifier.issn	0022-3751
dc.identifier.issn	1469-7793
dc.identifier.uri	https://hdl.handle.net/2027.42/177290
dc.description.abstract	This white paper is the outcome of the seventh UC Davis Cardiovascular Research Symposium on Systems Approach to Understanding Cardiovascular Disease and Arrhythmia. This biannual meeting aims to bring together leading experts in subfields of cardiovascular biomedicine to focus on topics of importance to the field. The theme of the 2022 Symposium was ‘Cell Diversity in the Cardiovascular System, cell-autonomous and cell–cell signalling’. Experts in the field contributed their experimental and mathematical modelling perspectives and discussed emerging questions, controversies, and challenges in examining cell and signal diversity, co-ordination and interrelationships involved in cardiovascular function. This paper originates from the topics of formal presentations and informal discussions from the Symposium, which aimed to develop a holistic view of how the multiple cell types in the cardiovascular system integrate to influence cardiovascular function, disease progression and therapeutic strategies. The first section describes the major cell types (e.g. cardiomyocytes, vascular smooth muscle and endothelial cells, fibroblasts, neurons, immune cells, etc.) and the signals involved in cardiovascular function. The second section emphasizes the complexity at the subcellular, cellular and system levels in the context of cardiovascular development, ageing and disease. Finally, the third section surveys the technological innovations that allow the interrogation of this diversity and advancing our understanding of the integrated cardiovascular function and dysfunction.Abstract figure legend This white paper discusses the cell diversity, co-ordination and interaction patterns that are critical for robust cardiovascular function. We identify the major cell types and signals involved in cardiovascular function and emphasize the complexity at the subcellular, cellular and system levels that motivate both challenges and opportunities for researchers. A survey of recent advances enabled by innovative experimental and computational modelling approaches serve to guide researchers moving forward.
dc.publisher	Wiley Periodicals, Inc.
dc.publisher	IOP Publishing Ltd
dc.subject.other	signal transduction
dc.subject.other	ion channels
dc.subject.other	ion transporters
dc.subject.other	modelling
dc.subject.other	omics
dc.subject.other	animal models
dc.title	Diversity of cells and signals in the cardiovascular system
dc.type	Article
dc.rights.robots	IndexNoFollow
dc.subject.hlbsecondlevel	Physiology
dc.subject.hlbtoplevel	Health Sciences
dc.description.peerreviewed	Peer Reviewed
dc.description.bitstreamurl	http://deepblue.lib.umich.edu/bitstream/2027.42/177290/1/tjp15436_am.pdf
dc.description.bitstreamurl	http://deepblue.lib.umich.edu/bitstream/2027.42/177290/2/tjp15436-sup-0001-PeerReview.pdf
dc.description.bitstreamurl	http://deepblue.lib.umich.edu/bitstream/2027.42/177290/3/tjp15436.pdf
dc.identifier.doi	10.1113/JP284011
dc.identifier.source	The Journal of Physiology
dc.identifier.citedreference	Radwanski, P. B., Johnson, C. N., Gyorke, S., & Veeraraghavan, R. ( 2018 ). Cardiac arrhythmias as manifestations of nanopathies: An emerging view. Frontiers in Physiology, 9, 1228.
dc.identifier.citedreference	Wagner, B. A., Venkataraman, S., & Buettner, G. R. ( 2011 ). The rate of oxygen utilization by cells. Free Radical Biology and Medicine, 51 ( 3 ), 700 – 712.
dc.identifier.citedreference	Wahler, G. M. ( 1992 ). Developmental increases in the inwardly rectifying potassium current of rat ventricular myocytes. American Journal of Physiology, 262 ( 5 ), C1266 – C1272.
dc.identifier.citedreference	Wainger, B. J., DeGennaro, M., Santoro, B., Siegelbaum, S. A., & Tibbs, G. R. ( 2001 ). Molecular mechanism of cAMP modulation of HCN pacemaker channels. Nature, 411 ( 6839 ), 805 – 810.
dc.identifier.citedreference	Wang, H. J., Wang, W., Cornish, K. G., Rozanski, G. J., & Zucker, I. H. ( 2014 ). Cardiac sympathetic afferent denervation attenuates cardiac remodeling and improves cardiovascular dysfunction in rats with heart failure. Hypertension, 64 ( 4 ), 745 – 755.
dc.identifier.citedreference	Wang, L., Feng, Z. P., Kondo, C. S., Sheldon, R. S., & Duff, H. J. ( 1996 ). Developmental changes in the delayed rectifier K+ channels in mouse heart. Circulation Research, 79 ( 1 ), 79 – 85.
dc.identifier.citedreference	Wang, Y., Pan, W., Bai, X., Wang, X., Wang, Y., & Yin, Y. ( 2021 ). microRNA-454-mediated NEDD4-2/TrkA/cAMP axis in heart failure: Mechanisms and cardioprotective implications. Journal of Cellular and Molecular Medicine, 25 ( 11 ), 5082 – 5098.
dc.identifier.citedreference	Wang, Y., Yao, F., Wang, L., Li, Z., Ren, Z., Li, D., Zhang, M., Han, L., Wang, S. Q., Zhou, B., & Wang, L. ( 2020 ). Single-cell analysis of murine fibroblasts identifies neonatal to adult switching that regulates cardiomyocyte maturation. Nature Communications, 11 ( 1 ), 2585.
dc.identifier.citedreference	Wang, Z., Gerstein, M., & Snyder, M. ( 2009 ). RNA-Seq: A revolutionary tool for transcriptomics. Nature Reviews Genetics, 10 ( 1 ), 57 – 63.
dc.identifier.citedreference	Wassie, A. T., Zhao, Y., & Boyden, E. S. ( 2019 ). Expansion microscopy: Principles and uses in biological research. Nature Methods, 16 ( 1 ), 33 – 41.
dc.identifier.citedreference	Weber, M., Leutenegger, M., Stoldt, S., Jakobs, S., Mihaila, T. S., Butkevich, A. N., & Hell, S. W. ( 2021 ). MINSTED fluorescence localization and nanoscopy. Nature Photonics, 15 ( 5 ), 361 – 366.
dc.identifier.citedreference	Weinberg, S. H. ( 2017 ). Ephaptic coupling rescues conduction failure in weakly coupled cardiac tissue with voltage-gated gap junctions. Chaos (Woodbury, NY), 27 ( 9 ), 093908.
dc.identifier.citedreference	Weiss, J. N., Karma, A., MacLellan, W. R., Deng, M., Rau, C. D., Rees, C. M., Wang, J., Wisniewski, N., Eskin, E., Horvath, S., Qu, Z., Wang, Y., & Lusis, A. J. ( 2012 ). “Good enough solutions” and the genetics of complex diseases. Circulation Research, 111 ( 4 ), 493 – 504.
dc.identifier.citedreference	Westcott, E. B., & Segal, S. S. ( 2013 ). Perivascular innervation: A multiplicity of roles in vasomotor control and myoendothelial signaling. Microcirculation, 20 ( 3 ), 217 – 238.
dc.identifier.citedreference	Westhoff, M., & Dixon, R. E. ( 2021 ). Mechanisms and regulation of cardiac CaV1.2 trafficking. International Journal of Molecular Sciences, 22 ( 11 ), 5927.
dc.identifier.citedreference	Wetzel, G. T., Chen, F., & Klitzner, T. S. ( 1995 ). Na + /Ca 2+ exchange and cell contraction in isolated neonatal and adult rabbit cardiac myocytes. American Journal of Physiology, 268, H1723 – H1733.
dc.identifier.citedreference	Whittaker, D. G., Clerx, M., Lei, C. L., Christini, D. J., & Mirams, G. R. ( 2020 ). Calibration of ionic and cellular cardiac electrophysiology models. Wiley Interdisciplinary Reviews: Systems Biology and Medicine, 12 ( 4 ), e1482.
dc.identifier.citedreference	Winslow, R. L., Walker, M. A., & Greenstein, J. L. ( 2016 ). Modeling calcium regulation of contraction, energetics, signaling, and transcription in the cardiac myocyte. Wiley Interdisciplinary Reviews: Systems Biology and Medicine, 8 ( 1 ), 37 – 67.
dc.identifier.citedreference	Withaar, C., Lam, C. S. P., Schiattarella, G. G., de Boer, R. A., & Meems, L. M. G. ( 2021 ). Heart failure with preserved ejection fraction in humans and mice: Embracing clinical complexity in mouse models. European Heart Journal, 42 ( 43 ), 4420 – 4430.
dc.identifier.citedreference	Workman, A. J., Kane, K. A., & Rankin, A. C. ( 2001 ). The contribution of ionic currents to changes in refractoriness of human atrial myocytes associated with chronic atrial fibrillation. Cardiovascular Research, 52 ( 2 ), 226 – 235.
dc.identifier.citedreference	Xie, Y., Yang, Y., Galice, S., Bers, D. M., & Sato, D. ( 2019 ). Size matters: Ryanodine receptor cluster size heterogeneity potentiates calcium waves. Biophysical Journal, 116 ( 3 ), 530 – 539.
dc.identifier.citedreference	Xu Parks, X., Qudsi, H., Braun, C., & Lopes, C. M. B. ( 2020 ). The auxiliary subunit KCNE1 regulates KCNQ1 channel response to sustained calcium-dependent PKC activation. PLoS One, 15 ( 8 ), e0237591.
dc.identifier.citedreference	Yang, D., Deschenes, I., & Fu, J. D. ( 2022 ). Multilayer control of cardiac electrophysiology by microRNAs. Journal of Molecular and Cellular Cardiology, 166, 107 – 115.
dc.identifier.citedreference	Yang, K. C., Yamada, K. A., Patel, A. Y., Topkara, V. K., George, I., Cheema, F. H., Ewald, G. A., Mann, D. L., & Nerbonne, J. M. ( 2014 ). Deep RNA sequencing reveals dynamic regulation of myocardial noncoding RNAs in failing human heart and remodeling with mechanical circulatory support. Circulation, 129 ( 9 ), 1009 – 1021.
dc.identifier.citedreference	Yang, P. C., Perissinotti, L. L., Lopez-Redondo, F., Wang, Y., DeMarco, K. R., Jeng, M. T., Vorobyov, I., Harvey, R. D., Kurokawa, J., Noskov, S. Y., & Clancy, C. E. ( 2017 ). A multiscale computational modelling approach predicts mechanisms of female sex risk in the setting of arousal-induced arrhythmias. The Journal of Physiology, 595 ( 14 ), 4695 – 4723.
dc.identifier.citedreference	Yang, X., Rodriguez, M., Pabon, L., Fischer, K. A., Reinecke, H., Regnier, M., Sniadecki, N. J., Ruohola-Baker, H., & Murry, C. E. ( 2014 ). Tri-iodo-l-thyronine promotes the maturation of human cardiomyocytes-derived from induced pluripotent stem cells. Journal of Molecular and Cellular Cardiology, 72, 296 – 304.
dc.identifier.citedreference	Yang, X., Rodriguez, M. L., Leonard, A., Sun, L., Fischer, K. A., Wang, Y., Ritterhoff, J., Zhao, L., Kolwicz, S. C., Jr., Pabon, L., Reinecke, H., Sniadecki, N. J., Tian, R., Ruohola-Baker, H., Xu, H., & Murry, C. E. ( 2019 ). Fatty acids enhance the maturation of cardiomyocytes derived from human pluripotent stem cells. Stem Cell Reports, 13 ( 4 ), 657 – 668.
dc.identifier.citedreference	Yaniv, Y., Stern, M. D., Lakatta, E. G., & Maltsev, V. A. ( 2013 ). Mechanisms of beat-to-beat regulation of cardiac pacemaker cell function by Ca(2)(+) cycling dynamics. Biophysical Journal, 105 ( 7 ), 1551 – 1561.
dc.identifier.citedreference	Yin, L., Zahradnikova, A., Jr., Rizzetto, R., Boncompagni, S., Rabesahala de Meritens, C., Zhang, Y., Joanne, P., Marques-Sule, E., Aguilar-Sanchez, Y., Fernandez-Tenorio, M., Villejoubert, O., Li, L., Wang, Y. Y., Mateo, P., Nicolas, V., Gerbaud, P., Lai, F. A., Perrier, R., Alvarez, J. L., … Gomez, A. M. ( 2021 ). Impaired binding to junctophilin-2 and nanostructural alteration in CPVT mutation. Circulation Research, 129 ( 3 ), e35 – e52.
dc.identifier.citedreference	Yu, J. K., Liang, J. A., Weinberg, S. H., & Trayanova, N. A. ( 2022 ). Computational modeling of aberrant electrical activity following remuscularization with intramyocardially injected pluripotent stem cell-derived cardiomyocytes. Journal of Molecular and Cellular Cardiology, 162, 97 – 109.
dc.identifier.citedreference	Zeigler, A. C., Chandrabhatla, A. S., Christiansen, S. L., Nelson, A. R., Holmes, J. W., & Saucerman, J. J. ( 2021 ). Network model-based screen for FDA-approved drugs affecting cardiac fibrosis. CPT Pharmacometrics & Systems Pharmacology, 10 ( 4 ), 377 – 388.
dc.identifier.citedreference	Zeigler, A. C., Richardson, W. J., Holmes, J. W., & Saucerman, J. J. ( 2016 ). Computational modeling of cardiac fibroblasts and fibrosis. Journal of Molecular and Cellular Cardiology, 93, 73 – 83.
dc.identifier.citedreference	Zhang, X., Ni, H., Morotti, S., Smith, C. E. R., Sato, D., Louch, W. E., Edwards, A. G., & Grandi, E. ( 2022 ). Mechanisms of spontaneous Ca(2+) release-mediated arrhythmia in a novel 3D human atrial myocyte model: I. Transverse-axial tubule variation. The Journal of Physiology, 601 ( 13 ), 2655 – 2683.
dc.identifier.citedreference	Zhang, X., Smith, C. E. R., Morotti, S., Edwards, A. G., Sato, D., Louch, W. E., Ni, H., & Grandi, E. ( 2022 ). Mechanisms of spontaneous Ca(2+) release-mediated arrhythmia in a novel 3D human atrial myocyte model: II Ca(2+) -handling protein variation. The Journal of Physiology, 601 ( 13 ), 2685 – 2710.
dc.identifier.citedreference	Zhang, Z., Xu, Y., Song, H., Rodriguez, J., Tuteja, D., Namkung, Y., Shin, H. S., & Chiamvimonvat, N. ( 2002 ). Functional roles of Ca(v)1.3 (alpha(1D)) calcium channel in sinoatrial nodes: Insight gained using gene-targeted null mutant mice. Circulation Research, 90 ( 9 ), 981 – 987.
dc.identifier.citedreference	Zhao, G., Joca, H. C., Nelson, M. T., & Lederer, W. J. ( 2020 ). ATP- and voltage-dependent electro-metabolic signaling regulates blood flow in heart. PNAS, 117 ( 13 ), 7461 – 7470.
dc.identifier.citedreference	Zhao, X. J., Zhu, C., Tian, L. Y., Fu, Y. C., Zhang, Y., Chen, X., Huang, Y., & Li, Y. ( 2017 ). Kv4.3 modulates the distribution of hERG. Scientific Reports, 7 ( 1 ), 17757.
dc.identifier.citedreference	Zhou, J., Singh, N., Monnier, C., Marszalec, W., Gao, L., Jin, J., Frisk, M., Louch, W. E., Verma, S., Krishnamurthy, P., Nico, E., Mulla, M., Aistrup, G. L., Kishore, R., & Wasserstrom, J. A. ( 2021 ). Phosphatidylinositol-4,5-bisphosphate binding to amphiphysin-II modulates T-tubule remodeling: Implications for heart failure. Front Physiol, 12, 782767.
dc.identifier.citedreference	Ziman, A. P., Gomez-Viquez, N. L., Bloch, R. J., & Lederer, W. J. ( 2010 ). Excitation-contraction coupling changes during postnatal cardiac development. Journal of Molecular and Cellular Cardiology, 48 ( 2 ), 379 – 386.
dc.identifier.citedreference	Zimmermann, W. H., Schneiderbanger, K., Schubert, P., Didie, M., Munzel, F., Heubach, J. F., Kostin, S., Neuhuber, W. L., & Eschenhagen, T. ( 2002 ). Tissue engineering of a differentiated cardiac muscle construct. Circulation Research, 90 ( 2 ), 223 – 230.
dc.identifier.citedreference	Asghari, P., Scriven, D. R., Ng, M., Panwar, P., Chou, K. C., van Petegem, F., & Moore, E. D. ( 2020 ). Cardiac ryanodine receptor distribution is dynamic and changed by auxiliary proteins and post-translational modification. Elife, 9.
dc.identifier.citedreference	Bakunts, K., Gillum, N., Karabekian, Z., & Sarvazyan, N. ( 2008 ). Formation of cardiac fibers in Matrigel matrix. Biotechniques, 44 ( 3 ), 341 – 348.
dc.identifier.citedreference	Aghasafari, P., Yang, P. C., Kernik, D. C., Sakamoto, K., Kanda, Y., Kurokawa, J., Vorobyov, I., & Clancy, C. E. ( 2021 ). A deep learning algorithm to translate and classify cardiac electrophysiology. Elife, 10.
dc.identifier.citedreference	Agullo-Pascual, E., Reid, D. A., Keegan, S., Sidhu, M., Fenyo, D., Rothenberg, E., & Delmar, M. ( 2013 ). Super-resolution fluorescence microscopy of the cardiac connexome reveals plakophilin-2 inside the connexin43 plaque. Cardiovascular Research, 100 ( 2 ), 231 – 240.
dc.identifier.citedreference	Ahern, B. M., Levitan, B. M., Veeranki, S., Shah, M., Ali, N., Sebastian, A., Su, W., Gong, M. C., Li, J., Stelzer, J. E., Andres, D. A., & Satin, J. ( 2019 ). Myocardial-restricted ablation of the GTPase RAD results in a pro-adaptive heart response in mice. Journal of Biological Chemistry, 294 ( 28 ), 10913 – 10927.
dc.identifier.citedreference	Alarcon-Martinez, L., Villafranca-Baughman, D., Quintero, H., Kacerovsky, J. B., Dotigny, F., Murai, K. K., Prat, A., Drapeau, P., & Di Polo, A. ( 2020 ). Interpericyte tunnelling nanotubes regulate neurovascular coupling. Nature, 585 ( 7823 ), 91 – 95.
dc.identifier.citedreference	Alvarado, M. G., Thakore, P., & Earley, S. ( 2021 ). Transient receptor potential channel ankyrin 1: A unique regulator of vascular function. Cells, 10 ( 5 ), 1167.
dc.identifier.citedreference	Amberg, G. C., & Navedo, M. F. ( 2013 ). Calcium dynamics in vascular smooth muscle. Microcirculation, 20 ( 4 ), 281 – 289.
dc.identifier.citedreference	Andrienko, T., Kuznetsov, A. V., Kaambre, T., Usson, Y., Orosco, A., Appaix, F., Tiivel, T., Sikk, P., Vendelin, M., Margreiter, R., & Saks, V. A. ( 2003 ). Metabolic consequences of functional complexes of mitochondria, myofibrils and sarcoplasmic reticulum in muscle cells. Journal of Experimental Biology, 206 ( 12 ), 2059 – 2072.
dc.identifier.citedreference	Angst, B. D., Khan, L. U., Severs, N. J., Whitely, K., Rothery, S., Thompson, R. P., Magee, A. I., & Gourdie, R. G. ( 1997 ). Dissociated spatial patterning of gap junctions and cell adhesion junctions during postnatal differentiation of ventricular myocardium. Circulation Research, 80 ( 1 ), 88 – 94.
dc.identifier.citedreference	Anversa, P., Li, P., Sonnenblick, E. H., & Olivetti, G. ( 1994 ). Effects of aging on quantitative structural properties of coronary vasculature and microvasculature in rats. American Journal of Physiology, 267, H1062 - H1073.
dc.identifier.citedreference	Aquino, J. B., Sierra, R., & Montaldo, L. A. ( 2021 ). Diverse cellular origins of adult blood vascular endothelial cells. Developmental Biology, 477, 117 – 132.
dc.identifier.citedreference	Arevalo, H. J., Vadakkumpadan, F., Guallar, E., Jebb, A., Malamas, P., Wu, K. C., & Trayanova, N. A. ( 2016 ). Arrhythmia risk stratification of patients after myocardial infarction using personalized heart models. Nature Communications, 7 ( 1 ), 11437.
dc.identifier.citedreference	Aromolaran, K. A., Do, J., Bernardi, J., & Aromolaran, A. S. ( 2022 ). mTOR modulation of IKr through hERG1b-dependent mechanisms in lipotoxic heart. International Journal of Molecular Sciences, 23 ( 15 ), 8061.
dc.identifier.citedreference	Ballouz, S., Mangala, M. M., Perry, M. D., Heitmann, S., Gillis, J. A., Hill, A. P., & Vandenberg, J. I. ( 2021 ). Co-expression of calcium and hERG potassium channels reduces the incidence of proarrhythmic events. Cardiovascular Research, 117 ( 10 ), 2216 – 2227.
dc.identifier.citedreference	Bannister, J. P., Bulley, S., Leo, M. D., Kidd, M. W., & Jaggar, J. H. ( 2016 ). Rab25 influences functional Cav1.2 channel surface expression in arterial smooth muscle cells. American journal of physiology Cell physiology, 310 ( 11 ), C885 – C893.
dc.identifier.citedreference	Bao, F., Deng, Y., Wan, S., Shen, S. Q., Wang, B., Dai, Q., Altschuler, S. J., & Wu, L. F. ( 2022 ). Integrative spatial analysis of cell morphologies and transcriptional states with MUSE. Nature Biotechnology, 40 ( 8 ), 1200 – 1209.
dc.identifier.citedreference	Bargehr, J., Ong, L. P., Colzani, M., Davaapil, H., Hofsteen, P., Bhandari, S., Gambardella, L., Le Novere, N., Iyer, D., Sampaziotis, F., Weinberger, F., Bertero, A., Leonard, A., Bernard, W. G., Martinson, A., Figg, N., Regnier, M., Bennett, M. R., Murry, C. E., & Sinha, S. ( 2019 ). Epicardial cells derived from human embryonic stem cells augment cardiomyocyte-driven heart regeneration. Nature Biotechnology, 37 ( 8 ), 895 – 906.
dc.identifier.citedreference	Barkaway, A., Attwell, D., & Korte, N. ( 2022 ). Immune-vascular mural cell interactions: Consequences for immune cell trafficking, cerebral blood flow, and the blood-brain barrier. Neurophotonics, 9 ( 03 ), 031914.
dc.identifier.citedreference	Barth, E., Stammler, G., Speiser, B., & Schaper, J. ( 1992 ). Ultrastructural quantitation of mitochondria and myofilaments in cardiac muscle from 10 different animal species including man. Journal of Molecular and Cellular Cardiology, 24 ( 7 ), 669 – 681.
dc.identifier.citedreference	Beliveau, B. J., Boettiger, A. N., Nir, G., Bintu, B., Yin, P., Zhuang, X., & Wu, C. T. ( 2017 ). In situ super-resolution imaging of genomic DNA with OligoSTORM and OligoDNA-PAINT. Methods in Molecular Biology, 1663, 231 – 252.
dc.identifier.citedreference	Bers, D. M. ( 2002 ). Cardiac excitation-contraction coupling. Nature, 415 ( 6868 ), 198 – 205.
dc.identifier.citedreference	Bers, D. M., Xiang, Y. K., & Zaccolo, M. ( 2019 ). Whole-cell cAMP and PKA activity are epiphenomena, nanodomain signaling matters. Physiology (Bethesda, Md), 34, 240 – 249.
dc.identifier.citedreference	Bhana, B., Iyer, R. K., Chen, W. L., Zhao, R., Sider, K. L., Likhitpanichkul, M., Simmons, C. A., & Radisic, M. ( 2010 ). Influence of substrate stiffness on the phenotype of heart cells. Biotechnology and Bioengineering, 105, 1148 – 1160.
dc.identifier.citedreference	Bhargava, A., Lin, X., Novak, P., Mehta, K., Korchev, Y., Delmar, M., & Gorelik, J. ( 2013 ). Super-resolution scanning patch clamp reveals clustering of functional ion channels in adult ventricular myocyte. Circulation Research, 112 ( 8 ), 1112 – 1120.
dc.identifier.citedreference	Biernacka, A., & Frangogiannis, N. G. ( 2011 ). Aging and cardiac fibrosis. Aging Dis, 2, 158 – 173.
dc.identifier.citedreference	Bishop, S. P., Anderson, P. G., & Tucker, D. C. ( 1990 ). Morphological development of the rat heart growing in oculo in the absence of hemodynamic work load. Circulation Research, 66 ( 1 ), 84 – 102.
dc.identifier.citedreference	Blatter, L. A., Kockskamper, J., Sheehan, K. A., Zima, A. V., Huser, J., & Lipsius, S. L. ( 2003 ). Local calcium gradients during excitation-contraction coupling and alternans in atrial myocytes. The Journal of Physiology, 546 ( 1 ), 19 – 31.
dc.identifier.citedreference	Bleck, C. K. E., Kim, Y., Willingham, T. B., & Glancy, B. ( 2018 ). Subcellular connectomic analyses of energy networks in striated muscle. Nature Communications, 9 ( 1 ), 5111.
dc.identifier.citedreference	Bogdanov, V., Soltisz, A. M., Moise, N., Sakuta, G., Orengo, B. H., Janssen, P. M. L., Weinberg, S. H., Davis, J. P., Veeraraghavan, R., & Gyorke, S. ( 2021 ). Distributed synthesis of sarcolemmal and sarcoplasmic reticulum membrane proteins in cardiac myocytes. Basic Research in Cardiology, 116 ( 1 ), 63.
dc.identifier.citedreference	Borile, G., Sandrin, D., Filippi, A., Anderson, K. I., & Romanato, F. ( 2021 ). Label-free multiphoton microscopy: Much more than fancy images. International Journal of Molecular Sciences, 22 ( 5 ), 2657.
dc.identifier.citedreference	Bowers, S., Meng, Q., & Molkentin, J. ( 2022 ). Fibroblasts orchestrate cellular crosstalk in the heart through the ECM. Nature Cardiovascular Research, 1 ( 4 ), 312 – 321.
dc.identifier.citedreference	Brandenburg, S., Pawlowitz, J., Steckmeister, V., Subramanian, H., Uhlenkamp, D., Scardigli, M., Mushtaq, M., Amlaz, S. I., Kohl, T., Wegener, J. W., Arvanitis, D. A., Sanoudou, D., Sacconi, L., Hasenfuss, G., Voigt, N., Nikolaev, V. O., & Lehnart, S. E. ( 2022 ). A junctional cAMP compartment regulates rapid Ca(2+) signaling in atrial myocytes. Journal of Molecular and Cellular Cardiology, 165, 141 – 157.
dc.identifier.citedreference	Breckenridge, R. A., Piotrowska, I., Ng, K. E., Ragan, T. J., West, J. A., Kotecha, S., Towers, N., Bennett, M., Kienesberger, P. C., Smolenski, R. T., Siddall, H. K., Offer, J. L., Mocanu, M. M., Yelon, D. M., Dyck, J. R., Griffin, J. L., Abramov, A. Y., Gould, A. P., & Mohun, T. J. ( 2013 ). Hypoxic regulation of hand1 controls the fetal-neonatal switch in cardiac metabolism. Plos Biology, 11 ( 9 ), e1001666.
dc.identifier.citedreference	Britton, O. J., Bueno-Orovio, A., Van Ammel, K., Lu, H. R., Towart, R., Gallacher, D. J., & Rodriguez, B. ( 2013 ). Experimentally calibrated population of models predicts and explains intersubject variability in cardiac cellular electrophysiology. PNAS, 110 ( 23 ), E2098 – E2105.
dc.identifier.citedreference	Bruno, R. M., Ghiadoni, L., Seravalle, G., Dell’oro, R., Taddei, S., & Grassi, G. ( 2012 ). Sympathetic regulation of vascular function in health and disease. Front Physiol, 3, 284.
dc.identifier.citedreference	Dobrev, D., & Wehrens, X. H. T. ( 2018 ). Mouse Models of Cardiac Arrhythmias. Circulation Research, 123 ( 3 ), 332 – 334.
dc.identifier.citedreference	Bryant, S. M., Kong, C. H., Watson, J., Cannell, M. B., James, A. F., & Orchard, C. H. ( 2015 ). Altered distribution of ICa impairs Ca release at the t-tubules of ventricular myocytes from failing hearts. Journal of Molecular and Cellular Cardiology, 86, 23 – 31.
dc.identifier.citedreference	Burnstock, G. ( 2009 ). Autonomic neurotransmission: 60 years since sir Henry Dale. Annual Review of Pharmacology and Toxicology, 49 ( 1 ), 1 – 30.
dc.identifier.citedreference	Burridge, P. W., Matsa, E., Shukla, P., Lin, Z. C., Churko, J. M., Ebert, A. D., Lan, F., Diecke, S., Huber, B., Mordwinkin, N. M., Plews, J. R., Abilez, O. J., Cui, B., Gold, J. D., & Wu, J. C. ( 2014 ). Chemically defined generation of human cardiomyocytes. Nature Methods, 11 ( 8 ), 855 – 860.
dc.identifier.citedreference	Bycroft, C., Freeman, C., Petkova, D., Band, G., Elliott, L. T., Sharp, K., Motyer, A., Vukcevic, D., Delaneau, O., O’Connell, J., Cortes, A., Welsh, S., Young, A., Effingham, M., McVean, G., Leslie, S., Allen, N., Donnelly, P., & Marchini, J. ( 2018 ). The UK Biobank resource with deep phenotyping and genomic data. Nature, 562 ( 7726 ), 203 – 209.
dc.identifier.citedreference	Caballero, R., de la Fuente, M. G., Gomez, R., Barana, A., Amoros, I., Dolz-Gaiton, P., Osuna, L., Almendral, J., Atienza, F., Fernandez-Aviles, F., Pita, A., Rodriguez-Roda, J., Pinto, A., Tamargo, J., & Delpon, E. ( 2010 ). In humans, chronic atrial fibrillation decreases the transient outward current and ultrarapid component of the delayed rectifier current differentially on each atria and increases the slow component of the delayed rectifier current in both. Journal of the American College of Cardiology, 55 ( 21 ), 2346 – 2354.
dc.identifier.citedreference	Cairns, D. I., Fenton, F. H., & Cherry, E. M. ( 2017 ). Efficient parameterization of cardiac action potential models using a genetic algorithm. Chaos (Woodbury, NY), 27 ( 9 ), 093922.
dc.identifier.citedreference	Carmeliet, E. ( 2019 ). Pacemaking in cardiac tissue. From IK2 to a coupled-clock system. Physiological Reports, 7 ( 1 ), e13862.
dc.identifier.citedreference	Carusi, A., Burrage, K., & Rodriguez, B. ( 2012 ). Bridging experiments, models and simulations: an integrative approach to validation in computational cardiac electrophysiology. American Journal of Physiology Heart and Circulatory Physiology, 303 ( 2 ), H144 – H155.
dc.identifier.citedreference	Cerbai, E., Pino, R., Sartiani, L., & Mugelli, A. ( 1999 ). Influence of postnatal-development on I(f) occurrence and properties in neonatal rat ventricular myocytes. Cardiovascular Research, 42 ( 2 ), 416 – 423.
dc.identifier.citedreference	Chalise, U., Becirovic-Agic, M., Konfrst, S. R., Rodriguez-Paar, J. R., Cook, L. M., & Lindsey, M. L. ( 2022 ). MMP-12 polarizes neutrophil signalome towards an apoptotic signature. Journal of Proteomics, 264, 104636.
dc.identifier.citedreference	Chamma, I., Levet, F., Sibarita, J. B., Sainlos, M., & Thoumine, O. ( 2016 ). Nanoscale organization of synaptic adhesion proteins revealed by single-molecule localization microscopy. Neurophotonics, 3 ( 4 ), 041810.
dc.identifier.citedreference	Chang, L., Garcia-Barrio, M. T., & Chen, Y. E. ( 2020 ). Perivascular adipose tissue regulates vascular function by targeting vascular smooth muscle cells. Arteriosclerosis, Thrombosis, and Vascular Biology, 40 ( 5 ), 1094 – 1109.
dc.identifier.citedreference	Chang, Z. H. ( 1988 ). Latent WPW syndrome diagnosed in Valsalva’s method. Kokyu to Junkan Respiration & Circulation, 36, 873 – 874.
dc.identifier.citedreference	Cheng, H., & Lederer, W. J. ( 2008 ). Calcium sparks. Physiological Reviews, 88 ( 4 ), 1491 – 1545.
dc.identifier.citedreference	Chowkwale, M., Lindsey, M. L., & Saucerman, J. J. ( 2022 ). Intercellular model predicts mechanisms of inflammation-fibrosis coupling after myocardial infarction. The Journal of Physiology, 601 ( 13 ), 2635 – 2654.
dc.identifier.citedreference	Clark, A. P., Wei, S., Kalola, D., Krogh-Madsen, T., & Christini, D. J. ( 2022 ). An in silico-in vitro pipeline for drug cardiotoxicity screening identifies ionic pro-arrhythmia mechanisms. British Journal of Pharmacology, 179 ( 20 ), 4829 – 4843,
dc.identifier.citedreference	Cole, W. C., & Welsh, D. G. ( 2011 ). Role of myosin light chain kinase and myosin light chain phosphatase in the resistance arterial myogenic response to intravascular pressure. Archives of Biochemistry and Biophysics, 510 ( 2 ), 160 – 173.
dc.identifier.citedreference	Colman, M. A. ( 2019 ). Arrhythmia mechanisms and spontaneous calcium release: Bi-directional coupling between re-entrant and focal excitation. Plos Computational Biology, 15 ( 8 ), e1007260.
dc.identifier.citedreference	Colman, M. A., Alvarez-Lacalle, E., Echebarria, B., Sato, D., Sutanto, H., & Heijman, J. ( 2022 ). Multi-scale computational modeling of spatial calcium handling from nanodomain to whole-heart: overview and perspectives. Frontiers in Physiology, 13, 836622.
dc.identifier.citedreference	Colman, M. A., Pinali, C., Trafford, A. W., Zhang, H., & Kitmitto, A. ( 2017 ). A computational model of spatio-temporal cardiac intracellular calcium handling with realistic structure and spatial flux distribution from sarcoplasmic reticulum and t-tubule reconstructions. Plos Computational Biology, 13 ( 8 ), e1005714.
dc.identifier.citedreference	Cooper, B. L., Gloschat, C., Swift, L. M., Prudencio, T., McCullough, D., Jaimes, R., & Posnack, N. G. ( 2021 ). KairoSight: Open-source software for the analysis of cardiac optical data collected from multiple species. Frontiers in Physiology, 12, 752940.
dc.identifier.citedreference	Corliss, B. A., Azimi, M. S., Munson, J. M., Peirce, S. M., & Murfee, W. L. ( 2016 ). Macrophages: An inflammatory link between angiogenesis and lymphangiogenesis. Microcirculation, 23 ( 2 ), 95 – 121.
dc.identifier.citedreference	Dobrev, D., & Wehrens, X. H. ( 2014 ). Role of RyR2 phosphorylation in heart failure and arrhythmias: Controversies around ryanodine receptor phosphorylation in cardiac disease. Circulation Research, 114 ( 8 ), 1311 – 1319; discussion 1319.
dc.identifier.citedreference	Corral-Acero, J., Margara, F., Marciniak, M., Rodero, C., Loncaric, F., Feng, Y., Gilbert, A., Fernandes, J. F., Bukhari, H. A., Wajdan, A., Martinez, M. V., Santos, M. S., Shamohammdi, M., Luo, H., Westphal, P., Leeson, P., DiAchille, P., Gurev, V., Mayr, M., … Lamata, P. ( 2020 ). The ‘Digital Twin’ to enable the vision of precision cardiology. European Heart Journal, 41 ( 48 ), 4556 – 4564.
dc.identifier.citedreference	Corti, A., Colombo, M., Migliavacca, F., Rodriguez Matas, J. F., Casarin, S., & Chiastra, C. ( 2021 ). Multiscale computational modeling of vascular adaptation: A systems biology approach using agent-based models. Frontiers in Bioengineering and Biotechnology, 9, 744560.
dc.identifier.citedreference	Costa, M. C., Roney, C., Strocchi, M., Razeghi, O., & Niederer, S. ( 2020 ). Clinical translation of patient-specific organ level cardiac models. In Krogh-Madsen T & Christini DJ ed. Modeling and simulating cardiac electrical activity, IOP Publishing Ltd.
dc.identifier.citedreference	Covarrubias, A. J., Kale, A., Perrone, R., Lopez-Dominguez, J. A., Pisco, A. O., Kasler, H. G., Schmidt, M. S., Heckenbach, I., Kwok, R., Wiley, C. D., Wong, H. S., Gibbs, E., Iyer, S. S., Basisty, N., Wu, Q., Kim, I. J., Silva, E., Vitangcol, K., Shin, K. O., … Verdin, E. ( 2020 ). Senescent cells promote tissue NAD(+) decline during ageing via the activation of CD38(+) macrophages. Nature Metabolism, 2 ( 11 ), 1265 – 1283.
dc.identifier.citedreference	Crotti, L., Tester, D. J., White, W. M., Bartos, D. C., Insolia, R., Besana, A., Kunic, J. D., Will, M. L., Velasco, E. J., Bair, J. J., Ghidoni, A., Cetin, I., Van Dyke, D. L., Wick, M. J., Brost, B., Delisle, B. P., Facchinetti, F., George, A. L., Schwartz, P. J., & Ackerman, M. J. ( 2013 ). Long QT syndrome-associated mutations in intrauterine fetal death. JAMA: The Journal of the American Medical Association, 309 ( 14 ), 1473 – 1482.
dc.identifier.citedreference	de Beer, M. A., & Giepmans, B. N. G. ( 2020 ). Nanobody-based probes for subcellular protein identification and visualization. Frontiers in Cellular Neuroscience, 14, 573278.
dc.identifier.citedreference	De Jongh, K. S., Murphy, B. J., Colvin, A. A., Hell, J. W., Takahashi, M., & Catterall, W. A. ( 1996 ). Specific phosphorylation of a site in the full-length form of the alpha 1 subunit of the cardiac L-type calcium channel by adenosine 3’,5’-cyclic monophosphate-dependent protein kinase. Biochemistry, 35 ( 32 ), 10392 – 10402.
dc.identifier.citedreference	De Maziere, A. M., van Ginneken, A. C., Wilders, R., Jongsma, H. J., & Bouman, L. N. ( 1992 ). Spatial and functional relationship between myocytes and fibroblasts in the rabbit sinoatrial node. Journal of Molecular and Cellular Cardiology, 24 ( 6 ), 567 – 578.
dc.identifier.citedreference	Del Villar, S. G., Voelker, T. L., Westhoff, M., Reddy, G. R., Spooner, H. C., Navedo, M. F., Dickson, E. J., & Dixon, R. E. ( 2021 ). beta-Adrenergic control of sarcolemmal CaV1.2 abundance by small GTPase Rab proteins. PNAS, 118 ( 7 ),
dc.identifier.citedreference	Di Carlo, S. E., & Peduto, L. ( 2018 ). The perivascular origin of pathological fibroblasts. Journal of Clinical Investigation, 128 ( 1 ), 54 – 63.
dc.identifier.citedreference	Dick, S. A., & Epelman, S. ( 2016 ). Chronic heart failure and inflammation: What do we really know? Circulation Research, 119 ( 1 ), 159 – 176.
dc.identifier.citedreference	Dick, S. A., Macklin, J. A., Nejat, S., Momen, A., Clemente-Casares, X., Althagafi, M. G., Chen, J., Kantores, C., Hosseinzadeh, S., Aronoff, L., Wong, A., Zaman, R., Barbu, I., Besla, R., Lavine, K. J., Razani, B., Ginhoux, F., Husain, M., Cybulsky, M. I., Robbins, C. S., & Epelman, S. ( 2019 ). Self-renewing resident cardiac macrophages limit adverse remodeling following myocardial infarction. Nature Immunology, 20 ( 1 ), 29 – 39.
dc.identifier.citedreference	Dillard, R. S., Hampton, C. M., Strauss, J. D., Ke, Z., Altomara, D., Guerrero-Ferreira, R. C., Kiss, G., & Wright, E. R. ( 2018 ). Biological applications at the cutting edge of cryo-electron microscopy. Microscopy and Microanalysis, 24 ( 4 ), 406 – 419.
dc.identifier.citedreference	Dixon, R. E., Moreno, C. M., Yuan, C., Opitz-Araya, X., Binder, M. D., Navedo, M. F., & Santana, L. F. ( 2015 ). Graded Ca(2)(+)/calmodulin-dependent coupling of voltage-gated CaV1.2 channels. Elife, 4.
dc.identifier.citedreference	Dixon, R. E., Navedo, M. F., Binder, M. D., & Santana, L. F. ( 2022 ). Mechanisms and physiological implications of cooperative gating of clustered ion channels. Physiological Reviews, 102 ( 3 ), 1159 – 1210.
dc.identifier.citedreference	Dixon, R. E., Vivas, O., Hannigan, K. I., & Dickson, E. J. ( 2017 ). Ground state depletion super-resolution imaging in mammalian cells. Journal of Visualized Experiments: JoVE, 129.
dc.identifier.citedreference	Dixon, R. E., Yuan, C., Cheng, E. P., Navedo, M. F., & Santana, L. F. ( 2012 ). Ca 2+ signaling amplification by oligomerization of L-type Cav1.2 channels. PNAS, 109 ( 5 ), 1749 – 1754.
dc.identifier.citedreference	Dobrev, D., Friedrich, A., Voigt, N., Jost, N., Wettwer, E., Christ, T., Knaut, M., & Ravens, U. ( 2005 ). The G protein-gated potassium current I(K,ACh) is constitutively active in patients with chronic atrial fibrillation. Circulation, 112 ( 24 ), 3697 – 3706.
dc.identifier.citedreference	Dobrev, D., Graf, E., Wettwer, E., Himmel, H. M., Hala, O., Doerfel, C., Christ, T., Schuler, S., & Ravens, U. ( 2001 ). Molecular basis of downregulation of G-protein-coupled inward rectifying K(+) current (I(K,ACh) in chronic human atrial fibrillation: Decrease in GIRK4 mRNA correlates with reduced I(K,ACh) and muscarinic receptor-mediated shortening of action potentials. Circulation, 104 ( 21 ), 2551 – 2557.
dc.identifier.citedreference	Dobrev, D., Heijman, J., Hiram, R., Li, N., & Nattel, S. ( 2022 ). Inflammatory signalling in atrial cardiomyocytes: A novel unifying principle in atrial fibrillation pathophysiology. Nature Reviews Cardiology, 20, 145 – 167.
dc.identifier.citedreference	Dobrev, D., & Ravens, U. ( 2003 ). Remodeling of cardiomyocyte ion channels in human atrial fibrillation. Basic Research in Cardiology, 98 ( 3 ), 137 – 148.
dc.identifier.citedreference	Doll, S., Dressen, M., Geyer, P. E., Itzhak, D. N., Braun, C., Doppler, S. A., Meier, F., Deutsch, M. A., Lahm, H., Lange, R., Krane, M., & Mann, M. ( 2017 ). Region and cell-type resolved quantitative proteomic map of the human heart. Nature Communications, 8 ( 1 ), 1469.
dc.identifier.citedreference	Dunn, K. K., Reichardt, I. M., Simmons, A. D., Jin, G., Floy, M. E., Hoon, K. M., & Palecek, S. P. ( 2019 ). Coculture of endothelial cells with human pluripotent stem cell-derived cardiac progenitors reveals a differentiation stage-specific enhancement of cardiomyocyte maturation. Biotechnology Journal, 14 ( 8 ), 1800725.
dc.identifier.citedreference	Durkee, M. S., Abraham, R., Clark, M. R., & Giger, M. L. ( 2021 ). Artificial intelligence and cellular segmentation in tissue microscopy images. American Journal of Pathology, 191 ( 10 ), 1693 – 1701.
dc.identifier.citedreference	Dwenger, M. M., Ohanyan, V., Navedo, M. F., & Nystoriak, M. A. ( 2018 ). Coronary microvascular Kv1 channels as regulatory sensors of intracellular pyridine nucleotide redox potential. Microcirculation, 25 ( 1 ), e12426.
dc.identifier.citedreference	Dwenger, M. M., Raph, S. M., Reyzer, M. L., Lisa Manier, M., Riggs, D. W., Wohl, Z. B., Ohanyan, V., Mack, G., Pucci, T., JBt, M., Hill, B. G., Chilian, W. M., Caprioli, R. M., Bhatnagar, A., & Nystoriak, M. A. ( 2022 ). Pyridine nucleotide redox potential in coronary smooth muscle couples myocardial blood flow to cardiac metabolism. Nature Communications, 13 ( 1 ), 2051.
dc.identifier.citedreference	Earley, S., & Brayden, J. E. ( 2015 ). Transient receptor potential channels in the vasculature. Physiological Reviews, 95 ( 2 ), 645 – 690.
dc.identifier.citedreference	Eichel, C. A., Rios-Perez, E. B., Liu, F., Jameson, M. B., Jones, D. K., Knickelbine, J. J., & Robertson, G. A. ( 2019 ). A microtranslatome coordinately regulates sodium and potassium currents in the human heart. Elife, 8.
dc.identifier.citedreference	Eichhorn, B., & Dobrev, D. ( 2007 ). Vascular large conductance calcium-activated potassium channels: Functional role and therapeutic potential. Naunyn-Schmiedebergs Archives of Pharmacology, 376 ( 3 ), 145 – 155.
dc.identifier.citedreference	Eisner, D. A., Caldwell, J. L., Kistamas, K., & Trafford, A. W. ( 2017 ). Calcium and excitation-contraction coupling in the heart. Circulation Research, 121 ( 2 ), 181 – 195.
dc.identifier.citedreference	Ernault, A. C., Meijborg, V. M. F., & Coronel, R. ( 2021 ). Modulation of cardiac arrhythmogenesis by epicardial adipose tissue: JACC state-of-the-art review. Journal of the American College of Cardiology, 78 ( 17 ), 1730 – 1745.
dc.identifier.citedreference	Erreni, M., Schorn, T., D’Autilia, F., & Doni, A. ( 2020 ). Nanobodies as versatile tool for multiscale imaging modalities. Biomolecules, 10 ( 12 ), 1695.
dc.identifier.citedreference	Es-Salah-Lamoureux, Z., Jouni, M., Malak, O. A., Belbachir, N., Al Sayed, Z. R., Gandon-Renard, M., Lamirault, G., Gauthier, C., Baró, I., Charpentier, F., Zibara, K., Lemarchand, P., Beaumelle, B., Gaborit, N., & Loussouarn, G. ( 2016 ). HIV-Tat induces a decrease in I(Kr) and I(Ks)via reduction in phosphatidylinositol-(4,5)-bisphosphate availability. Journal of Molecular and Cellular Cardiology, 99, 1 – 13.
dc.identifier.citedreference	Escobar, A. L., Ribeiro-Costa, R., Villalba-Galea, C., Zoghbi, M. E., Perez, C. G., & Mejia-Alvarez, R. ( 2004 ). Developmental changes of intracellular Ca 2+ transients in beating rat hearts. American Journal of Physiology Heart and Circulatory Physiology, 286 ( 3 ), H971 – H978.
dc.identifier.citedreference	Feaster, T. K., Cadar, A. G., Wang, L., Williams, C. H., Chun, Y. W., Hempel, J. E., Bloodworth, N., Merryman, W. D., Lim, C. C., Wu, J. C., Knollmann, B. C., & Hong, C. C. ( 2015 ). Matrigel mattress: A method for the generation of single contracting human-induced pluripotent stem cell-derived cardiomyocytes. Circulation Research, 117 ( 12 ), 995 – 1000.
dc.identifier.citedreference	Feigl, E. O. ( 1983 ). Coronary physiology. Physiological Reviews, 63 ( 1 ), 1 – 205.
dc.identifier.citedreference	Feyen, D. A. M., McKeithan, W. L., Bruyneel, A. A. N., Spiering, S., Hormann, L., Ulmer, B., Zhang, H., Briganti, F., Schweizer, M., Hegyi, B., Liao, Z., Polonen, R. P., Ginsburg, K. S., Lam, C. K., Serrano, R., Wahlquist, C., Kreymerman, A., Vu, M., Amatya, P. L., … Mercola, M. ( 2020 ). Metabolic maturation media improve physiological function of human iPSC-derived cardiomyocytes. Cell Reports, 32 ( 3 ), 107925.
dc.identifier.citedreference	Fink, M., Niederer, S. A., Cherry, E. M., Fenton, F. H., Koivumaki, J. T., Seemann, G., Thul, R., Zhang, H., Sachse, F. B., Beard, D., Crampin, E. J., & Smith, N. P. ( 2011 ). Cardiac cell modelling: observations from the heart of the cardiac physiome project. Progress in Biophysics and Molecular Biology, 104 ( 1–3 ), 2 – 21.
dc.identifier.citedreference	Francis Stuart, S. D., De Jesus, N. M., Lindsey, M. L., & Ripplinger, C. M. ( 2016 ). The crossroads of inflammation, fibrosis, and arrhythmia following myocardial infarction. Journal of Molecular and Cellular Cardiology, 91, 114 – 122.
dc.identifier.citedreference	Frangogiannis, N. G. ( 2019 ). Cardiac fibrosis: Cell biological mechanisms, molecular pathways and therapeutic opportunities. Molecular Aspects of Medicine, 65, 70 – 99.
dc.identifier.citedreference	Frodermann, V., & Nahrendorf, M. ( 2018 ). Macrophages and cardiovascular health. Physiological Reviews, 98, 2523 – 2569.
dc.identifier.citedreference	Fu, Y., Shaw, S. A., Naami, R., Vuong, C. L., Basheer, W. A., Guo, X., & Hong, T. ( 2016 ). Isoproterenol promotes rapid ryanodine receptor movement to bridging integrator 1 (BIN1)-organized dyads. Circulation, 133 ( 4 ), 388 – 397.
dc.identifier.citedreference	Gaborit, N., Steenman, M., Lamirault, G., Le Meur, N., Le Bouter, S., Lande, G., Leger, J., Charpentier, F., Christ, T., Dobrev, D., Escande, D., Nattel, S., & Demolombe, S. ( 2005 ). Human atrial ion channel and transporter subunit gene-expression remodeling associated with valvular heart disease and atrial fibrillation. Circulation, 112 ( 4 ), 471 – 481.
dc.identifier.citedreference	Galice, S., Xie, Y., Yang, Y., Sato, D., & Bers, D. M. ( 2018 ). Size matters: Ryanodine receptor cluster size affects arrhythmogenic sarcoplasmic reticulum calcium release. Journal of the American Heart Association, 7 ( 13 ),
dc.identifier.citedreference	Gallagher, B. R., & Zhao, Y. ( 2021 ). Expansion microscopy: A powerful nanoscale imaging tool for neuroscientists. Neurobiology of Disease, 154, 105362.
dc.identifier.citedreference	Gaujoux, R., & Seoighe, C. ( 2010 ). A flexible R package for nonnegative matrix factorization. BMC Bioinformatics [Electronic Resource], 11 ( 1 ), 367.
dc.identifier.citedreference	Gaur, N., & Rudy, Y. ( 2011 ). Multiscale modeling of calcium cycling in cardiac ventricular myocyte: macroscopic consequences of microscopic dyadic function. Biophysical Journal, 100 ( 12 ), 2904 – 2912.
dc.identifier.citedreference	Gawalko, M., Saljic, A., Li, N., Abu-Taha, I., Jespersen, T., Linz, D., Nattel, S., Heijman, J., Fender, A., & Dobrev, D. ( 2022 ). Adiposity-associated atrial fibrillation: Molecular determinants, mechanisms and clinical significance. Cardiovascular Research.
dc.identifier.citedreference	Genomes Project, C., Auton, A., Brooks, L. D., Durbin, R. M., Garrison, E. P., Kang, H. M., Korbel, J. O., Marchini, J. L., McCarthy, S., McVean, G. A., & Abecasis, G. R. ( 2015 ). A global reference for human genetic variation. Nature, 526, 68 – 74.
dc.identifier.citedreference	Ghosh, D., Nieves-Cintron, M., Tajada, S., Brust-Mascher, I., Horne, M. C., Hell, J. W., Dixon, R. E., Santana, L. F., & Navedo, M. F. ( 2018 ). Dynamic L-type CaV1.2 channel trafficking facilitates CaV1.2 clustering and cooperative gating. Biochimica et Biophysica Acta – Molecular Cell Research, 1865 ( 9 ), 1341 – 1355.
dc.identifier.citedreference	Giacomelli, E., Meraviglia, V., Campostrini, G., Cochrane, A., Cao, X., van Helden, R. W. J., Krotenberg Garcia, A., Mircea, M., Kostidis, S., Davis, R. P., van Meer, B. J., Jost, C. R., Koster, A. J., Mei, H., Miguez, D. G., Mulder, A. A., Ledesma-Terron, M., Pompilio, G., Sala, L., … Mummery, C. L. ( 2020 ). Human-iPSC-derived cardiac stromal cells enhance maturation in 3D cardiac microtissues and reveal non-cardiomyocyte contributions to heart disease. Cell Stem Cell, 26 ( 6 ), 862 – 879.e11 e811.
dc.identifier.citedreference	Giannetti, F., Benzoni, P., Campostrini, G., Milanesi, R., Bucchi, A., Baruscotti, M., Dell’Era, P., Rossini, A., & Barbuti, A. ( 2021 ). A detailed characterization of the hyperpolarization-activated “funny” current (If) in human-induced pluripotent stem cell (iPSC)-derived cardiomyocytes with pacemaker activity. Pflugers Archiv: European Journal of Physiology, 473 ( 7 ), 1009 – 1021.
dc.identifier.citedreference	Gong, J. Q. X., & Sobie, E. A. ( 2018 ). Population-based mechanistic modeling allows for quantitative predictions of drug responses across cell types. NPJ System Biology and Applucations, 4 ( 1 ), 11.
dc.identifier.citedreference	Gonzales, A. L., Klug, N. R., Moshkforoush, A., Lee, J. C., Lee, F. K., Shui, B., Tsoukias, N. M., Kotlikoff, M. I., Hill-Eubanks, D., & Nelson, M. T. ( 2020 ). Contractile pericytes determine the direction of blood flow at capillary junctions. PNAS, 117 ( 43 ), 27022 – 27033.
dc.identifier.citedreference	Gorelik, J., Shevchuk, A., Ramalho, M., Elliott, M., Lei, C., Higgins, C. F., Lab, M. J., Klenerman, D., Krauzewicz, N., & Korchev, Y. ( 2002 ). Scanning surface confocal microscopy for simultaneous topographical and fluorescence imaging: application to single virus-like particle entry into a cell. PNAS, 99 ( 25 ), 16018 – 16023.
dc.identifier.citedreference	Goversen, B., van der Heyden, M. A. G., Veen, van T. A. B., & Boer, de T. P. ( 2018 ). The immature electrophysiological phenotype of iPSC-CMs still hampers in vitro drug screening: Special focus on IK1. Pharmacology & Therapeutics, 183, 127 – 136.
dc.identifier.citedreference	Grandi, E., Sanguinetti, M. C., Bartos, D. C., Bers, D. M., Chen-Izu, Y., Chiamvimonvat, N., Colecraft, H. M., Delisle, B. P., Heijman, J., Navedo, M. F., Noskov, S., Proenza, C., Vandenberg, J. I., & Yarov-Yarovoy, V. ( 2017 ). Potassium channels in the heart: structure, function and regulation. The Journal of Physiology, 595 ( 7 ), 2209 – 2228.
dc.identifier.citedreference	Greene, D., Kaboudian, A., Wasserstrom, J. A., Fenton, F. H., & Shiferaw, Y. ( 2022 ). Voltage-mediated mechanism for calcium wave synchronization and arrhythmogenesis in atrial tissue. Biophysical Journal, 121 ( 3 ), 383 – 395.
dc.identifier.citedreference	Greenstein, J. L., & Winslow, R. L. ( 2002 ). An integrative model of the cardiac ventricular myocyte incorporating local control of Ca 2+ release. Biophysical Journal, 83 ( 6 ), 2918 – 2945.
dc.identifier.citedreference	Greer-Short, A., George, S. A., Poelzing, S., & Weinberg, S. H. ( 2017 ). Revealing the concealed nature of long-QT type 3 syndrome. Circulation: Arrhythmia and Electrophysiology, 10 ( 2 ), e004400.
dc.identifier.citedreference	Groenendaal, W., Ortega, F. A., Kherlopian, A. R., Zygmunt, A. C., Krogh-Madsen, T., & Christini, D. J. ( 2015 ). Cell-specific cardiac electrophysiology models. Plos Computational Biology, 11 ( 4 ), e1004242.
dc.identifier.citedreference	Grune, J., Lewis, A. J. M., Yamazoe, M., Hulsmans, M., Rohde, D., Xiao, L., Zhang, S., Ott, C., Calcagno, D. M., Zhou, Y., Timm, K., Shanmuganathan, M., Pulous, F. E., Schloss, M. J., Foy, B. H., Capen, D., Vinegoni, C., Wojtkiewicz, G. R., Iwamoto, Y., … Nahrendorf, M. ( 2022 ). Neutrophils incite and macrophages avert electrical storm after myocardial infarction. Nature Cardiovascular Research, 1 ( 7 ), 649 – 664.
dc.identifier.citedreference	Guo, A., Wang, Y., Chen, B., Wang, Y., Yuan, J., Zhang, L., Hall, D., Wu, J., Shi, Y., Zhu, Q., Chen, C., Thiel, W. H., Zhan, X., Weiss, R. M., Zhan, F., Musselman, C. A., Pufall, M., Zhu, W., Au, K. F., … Song, L. S. ( 2018 ). E-C coupling structural protein junctophilin-2 encodes a stress-adaptive transcription regulator. Science, 362 ( 6421 ).
dc.identifier.citedreference	Hermosilla, T., Encina, M., Morales, D., Moreno, C., Conejeros, C., Alfaro-Valdes, H. M., Lagos-Meza, F., Simon, F., Altier, C., & Varela, D. ( 2017 ). Prolonged AT1R activation induces CaV1.2 channel internalization in rat cardiomyocytes. Scientific Reports, 7 ( 1 ), 10131.
dc.identifier.citedreference	Guo, J., Wang, T., Li, X., Shallow, H., Yang, T., Li, W., Xu, J., Fridman, M. D., Yang, X., & Zhang, S. ( 2012 ). Cell surface expression of human ether-a-go-go-related gene (hERG) channels is regulated by caveolin-3 protein via the ubiquitin ligase Nedd4-2. Journal of Biological Chemistry, 287 ( 40 ), 33132 – 33141.
dc.identifier.citedreference	Gwosch, K. C., Pape, J. K., Balzarotti, F., Hoess, P., Ellenberg, J., Ries, J., & Hell, S. W. ( 2020 ). MINFLUX nanoscopy delivers 3D multicolor nanometer resolution in cells. Nature Methods, 17 ( 2 ), 217 – 224.
dc.identifier.citedreference	Ha, T., Kaiser, C., Myong, S., Wu, B., & Xiao, J. ( 2022 ). Next generation single-molecule techniques: Imaging, labeling, and manipulation in vitro and in cellulo. Molecular Cell, 82 ( 2 ), 304 – 314.
dc.identifier.citedreference	Hadaya, J., & Ardell, J. L. ( 2020 ). Autonomic modulation for cardiovascular disease. Frontiers in Physiology, 11, 617459.
dc.identifier.citedreference	Haddock, P. S., Coetzee, W. A., Cho, E., Porter, L., Katoh, H., Bers, D. M., Jafri, M. S., & Artman, M. ( 1999 ). Subcellular [Ca2+]i gradients during excitation-contraction coupling in newborn rabbit ventricular myocytes. Circulation Research, 85 ( 5 ), 415 – 427.
dc.identifier.citedreference	Hahn, V. S., Knutsdottir, H., Luo, X., Bedi, K., Margulies, K. B., Haldar, S. M., Stolina, M., Yin, J., Khakoo, A. Y., Vaishnav, J., Bader, J. S., Kass, D. A., & Sharma, K. ( 2021 ). Myocardial gene expression signatures in human heart failure with preserved ejection fraction. Circulation, 143 ( 2 ), 120 – 134.
dc.identifier.citedreference	Hamaguchi, S., Kawakami, Y., Honda, Y., Nemoto, K., Sano, A., Namekata, I., & Tanaka, H. ( 2013 ). Developmental changes in excitation-contraction mechanisms of the mouse ventricular myocardium as revealed by functional and confocal imaging analyses. Journal of Pharmacological Sciences, 123 ( 2 ), 167 – 175.
dc.identifier.citedreference	Hamon, D., Rajendran, P. S., Chui, R. W., Ajijola, O. A., Irie, T., Talebi, R., Salavatian, S., Vaseghi, M., Bradfield, J. S., Armour, J. A., Ardell, J. L., & Shivkumar, K. ( 2017 ). Premature ventricular contraction coupling interval variability destabilizes cardiac neuronal and electrophysiological control: Insights from simultaneous cardioneural mapping. Circ Arrhythm Electrophysiol, 10 ( 4 ), e004937.
dc.identifier.citedreference	Hanna, P., Rajendran, P. S., Ajijola, O. A., Vaseghi, M., Andrew Armour, J., Ardell, J. L., & Shivkumar, K. ( 2017 ). Cardiac neuroanatomy – Imaging nerves to define functional control. Autonomic Neuroscience, 207, 48 – 58.
dc.identifier.citedreference	Hariharan, A., Weir, N., Robertson, C., He, L., Betsholtz, C., & Longden, T. A. ( 2020 ). The ion channel and GPCR toolkit of brain capillary pericytes. Frontiers in Cellular Neuroscience, 14, 601324.
dc.identifier.citedreference	Harlaar, N., Dekker, S. O., Zhang, J., Snabel, R. R., Veldkamp, M. W., Verkerk, A. O., Fabres, C. C., Schwach, V., Lerink, L. J. S., Rivaud, M. R., Mulder, A. A., Corver, W. E., Goumans, M., Dobrev, D., Klautz, R. J. M., Schalij, M. J., Veenstra, G. J. C., Passier, R., van Brakel, T. J., … de Vries, A. A. F. ( 2022 ). Conditional immortalization of human atrial myocytes for the generation of in vitro models of atrial fibrillation. Nature Biomedical Engineering, 6 ( 4 ), 389 – 402.
dc.identifier.citedreference	Harrison, C. B., Trevelin, S. C., Richards, D. A., Santos, C. X. C., Sawyer, G., Markovinovic, A., Zhang, X., Zhang, M., Brewer, A. C., Yin, X., Mayr, M., & Shah, A. M. ( 2021 ). Fibroblast Nox2 (NADPH Oxidase-2) regulates ANG II (angiotensin II)-induced vascular remodeling and hypertension via paracrine signaling to vascular smooth muscle cells. Arteriosclerosis, Thrombosis, and Vascular Biology, 41 ( 2 ), 698 – 710.
dc.identifier.citedreference	Hartmann, D. A., Coelho-Santos, V., & Shih, A. Y. ( 2022 ). Pericyte control of blood flow across microvascular zones in the central nervous system. Annual Review of Physiology, 84 ( 1 ), 331 – 354.
dc.identifier.citedreference	He, K., Shi, X., Zhang, X., Dang, S., Ma, X., Liu, F., Xu, M., Lv, Z., Han, D., Fang, X., & Zhang, Y. ( 2011 ). Long-distance intercellular connectivity between cardiomyocytes and cardiofibroblasts mediated by membrane nanotubes. Cardiovascular Research, 92 ( 1 ), 39 – 47.
dc.identifier.citedreference	Hegyi, B., Bossuyt, J., Griffiths, L. G., Shimkunas, R., Coulibaly, Z., Jian, Z., Grimsrud, K. N., Sondergaard, C. S., Ginsburg, K. S., Chiamvimonvat, N., Belardinelli, L., Varro, A., Papp, J. G., Pollesello, P., Levijoki, J., Izu, L. T., Boyd, W. D., Banyasz, T., Bers, D. M., & Chen-Izu, Y. ( 2018 ). Complex electrophysiological remodeling in postinfarction ischemic heart failure. PNAS, 115 ( 13 ), E3036 – E3044.
dc.identifier.citedreference	Hegyi, B., Chen-Izu, Y., Izu, L. T., Rajamani, S., Belardinelli, L., Bers, D. M., & Banyasz, T. ( 2020 ). Balance between rapid delayed rectifier K(+) current and late Na(+) current on ventricular repolarization: An effective antiarrhythmic target? Circulation: Arrhythmia and Electrophysiology, 13 ( 4 ), e008130.
dc.identifier.citedreference	Heidi Au, H. T., Cui, B., Chu, Z. E., Veres, T., & Radisic, M. ( 2009 ). Cell culture chips for simultaneous application of topographical and electrical cues enhance phenotype of cardiomyocytes. Lab on A Chip, 9 ( 4 ), 564 – 575.
dc.identifier.citedreference	Heijman, J., Muna, A. P., Veleva, T., Molina, C. E., Sutanto, H., Tekook, M., Wang, Q., Abu-Taha, I. H., Gorka, M., Kunzel, S., El-Armouche, A., Reichenspurner, H., Kamler, M., Nikolaev, V., Ravens, U., Li, N., Nattel, S., Wehrens, X. H. T., & Dobrev, D. ( 2020 ). Atrial myocyte NLRP3/CaMKII nexus forms a substrate for postoperative atrial fibrillation. Circulation Research, 127 ( 8 ), 1036 – 1055.
dc.identifier.citedreference	Heijman, J., Voigt, N., Nattel, S., & Dobrev, D. ( 2014 ). Cellular and molecular electrophysiology of atrial fibrillation initiation, maintenance, and progression. Circulation Research, 114 ( 9 ), 1483 – 1499.
dc.identifier.citedreference	Heiligenstein, X., & Lucas, M. S. ( 2022 ). One for all, all for one: A close look at in-resin fluorescence protocols for CLEM. Frontiers in Cell and Developmental Biology, 10, 866472.
dc.identifier.citedreference	Herron, T. J., Rocha, A. M., Campbell, K. F., Ponce-Balbuena, D., Willis, B. C., Guerrero-Serna, G., Liu, Q., Klos, M., Musa, H., Zarzoso, M., Bizy, A., Furness, J., Anumonwo, J., Mironov, S., & Jalife, J. ( 2016 ). Extracellular matrix-mediated maturation of human pluripotent stem cell-derived cardiac monolayer structure and electrophysiological function. Circ Arrhythm Electrophysiol, 9 ( 4 ), e003638.
dc.identifier.citedreference	Heusch, G. ( 2022 ). Coronary blood flow in heart failure: cause, consequence and bystander. Basic Research in Cardiology, 117 ( 1 ), 1.
dc.identifier.citedreference	Hew, K. W., & Keller, K. A. ( 2003 ). Postnatal anatomical and functional development of the heart: A species comparison. Birth Defects Research Part B, Developmental and Reproductive Toxicology, 68 ( 4 ), 309 – 320.
dc.identifier.citedreference	Hichri, E., Abriel, H., & Kucera, J. P. ( 2018 ). Distribution of cardiac sodium channels in clusters potentiates ephaptic interactions in the intercalated disc. The Journal of Physiology, 596 ( 4 ), 563 – 589.
dc.identifier.citedreference	Hill, M. C., Kadow, Z. A., Long, H., Morikawa, Y., Martin, T. J., Birks, E. J., Campbell, K. S., Nerbonne, J., Lavine, K., Wadhwa, L., Wang, J., Turaga, D., Adachi, I., & Martin, J. F. ( 2022 ). Integrated multi-omic characterization of congenital heart disease. Nature, 608 ( 7921 ), 181 – 191.
dc.identifier.citedreference	Hissen, S. L., & Taylor, C. E. ( 2020 ). Sex differences in vascular transduction of sympathetic nerve activity. Clinical Autonomic Research, 30 ( 5 ), 381 – 392.
dc.identifier.citedreference	Holzem, K. M., Gomez, J. F., Glukhov, A. V., Madden, E. J., Koppel, A. C., Ewald, G. A., Trenor, B., & Efimov, I. R. ( 2015 ). Reduced response to I blockade and altered hERG1a/1b stoichiometry in human heart failure. Journal of Molecular and Cellular Cardiology, 96, 82 – 92.
dc.identifier.citedreference	Hong, H., & Tian, X. Y. ( 2020 ). The role of macrophages in vascular repair and regeneration after ischemic injury. International Journal of Molecular Sciences, 21 ( 17 ), 6328.
dc.identifier.citedreference	Horvath, B., Kiss, D., Dienes, C., Hezso, T., Kovacs, Z., Szentandrassy, N., Almassy, J., Magyar, J., Banyasz, T., & Nanasi, P. P. ( 2021 ). Ion current profiles in canine ventricular myocytes obtained by the “onion peeling” technique. Journal of Molecular and Cellular Cardiology, 158, 153 – 162.
dc.identifier.citedreference	Hota, S. K., Rao, K. S., Blair, A. P., Khalilimeybodi, A., Hu, K. M., Thomas, R., So, K., Kameswaran, V., Xu, J., Polacco, B. J., Desai, R. V., Chatterjee, N., Hsu, A., Muncie, J. M., Blotnick, A. M., Winchester, S. A. B., Weinberger, L. S., Huttenhain, R., Kathiriya, I. S., … Bruneau, B. G. ( 2022 ). Brahma safeguards canalization of cardiac mesoderm differentiation. Nature, 602 ( 7895 ), 129 – 134.
dc.identifier.citedreference	Hou, Y., Bai, J., Shen, X., de Langen, O., Li, A., Lal, S., Dos Remedios, C. G., Baddeley, D., Ruygrok, P. N., Soeller, C., & Crossman, D. J. ( 2021 ). Nanoscale organisation of ryanodine receptors and junctophilin-2 in the failing human heart. Frontiers in Physiology, 12, 724372.
dc.identifier.citedreference	Huang, J., Hove-Madsen, L., & Tibbits, G. F. ( 2005 ). Na + /Ca 2+ exchange activity in neonatal rabbit ventricular myocytes. American Journal of Physiology Cell Physiology, 288 ( 1 ), C195 – C203.
dc.identifier.citedreference	Hulme, J. T., Westenbroek, R. E., Scheuer, T., & Catterall, W. A. ( 2006 ). Phosphorylation of serine 1928 in the distal C-terminal domain of cardiac CaV1.2 channels during beta1-adrenergic regulation. PNAS, 103 ( 44 ), 16574 – 16579.
dc.identifier.citedreference	Hulsmans, M., Clauss, S., Xiao, L., Aguirre, A. D., King, K. R., Hanley, A., Hucker, W. J., Wulfers, E. M., Seemann, G., Courties, G., Iwamoto, Y., Sun, Y., Savol, A. J., Sager, H. B., Lavine, K. J., Fishbein, G. A., Capen, D. E., Da Silva, N., Miquerol, L., … Nahrendorf, M. ( 2017 ). Macrophages facilitate electrical conduction in the heart. Cell, 169 ( 3 ), 510 – 522.e20 e520.
dc.identifier.citedreference	Inoue, R., Jensen, L. J., Jian, Z., Shi, J., Hai, L., Lurie, A. I., Henriksen, F. H., Salomonsson, M., Morita, H., Kawarabayashi, Y., Mori, M., Mori, Y., & Ito, Y. ( 2009 ). Synergistic activation of vascular TRPC6 channel by receptor and mechanical stimulation via phospholipase C/diacylglycerol and phospholipase A2/omega-hydroxylase/20-HETE pathways. Circulation Research, 104 ( 12 ), 1399 – 1409.
dc.identifier.citedreference	Ito, D. W., Hannigan, K. I., Ghosh, D., Xu, B., Del Villar, S. G., Xiang, Y. K., Dickson, E. J., Navedo, M. F., & Dixon, R. E. ( 2019 ). beta-adrenergic-mediated dynamic augmentation of sarcolemmal CaV 1.2 clustering and co-operativity in ventricular myocytes. The Journal of Physiology, 597 ( 8 ), 2139 – 2162.
dc.identifier.citedreference	Ivanovic, E., & Kucera, J. P. ( 2021 ). Localization of Na(+) channel clusters in narrowed perinexi of gap junctions enhances cardiac impulse transmission via ephaptic coupling: A model study. The Journal of Physiology, 599 ( 21 ), 4779 – 4811.
dc.identifier.citedreference	Jacquemet, G., Carisey, A. F., Hamidi, H., Henriques, R., & Leterrier, C. ( 2020 ). The cell biologist’s guide to super-resolution microscopy. Journal of Cell Science 133.
dc.identifier.citedreference	Jeong, D., & Kim, D. ( 2022 ). Recent developments in correlative super-resolution fluorescence microscopy and electron microscopy. Molecules and Cells, 45 ( 1 ), 41 – 50.
dc.identifier.citedreference	Johnson, E. K., Matkovich, S. J., & Nerbonne, J. M. ( 2018 ). Regional differences in mRNA and lncRNA expression profiles in non-failing human atria and ventricles. Scientific Reports, 8 ( 1 ), 13919.
dc.identifier.citedreference	Johnson, E. K., Springer, S. J., Wang, W., Dranoff, E. J., Zhang, Y., Kanter, E. M., Yamada, K. A., & Nerbonne, J. M. ( 2018 ). Differential expression and remodeling of transient outward potassium currents in human left ventricles. Circulation: Arrhythmia and Electrophysiology, 11 ( 1 ), e005914.
dc.identifier.citedreference	Jones, D. K., Liu, F., Vaidyanathan, R., Eckhardt, L. L., Trudeau, M. C., & Robertson, G. A. ( 2014 ). hERG 1b is critical for human cardiac repolarization. PNAS, 111 ( 50 ), 18073 – 18077.
dc.identifier.citedreference	Jones, E. M., Roti Roti, E. C., Wang, J., Delfosse, S. A., & Robertson, G. A. ( 2004 ). Cardiac IKr channels minimally comprise hERG 1a and 1b subunits. Journal of Biological Chemistry, 279 ( 43 ), 44690 – 44694.
dc.identifier.citedreference	Jopling, C., Sune, G., Faucherre, A., Fabregat, C. & Izpisua Belmonte, J. C. ( 2012 ). Hypoxia induces myocardial regeneration in zebrafish. Circulation, 126 ( 25 ), 3017 – 3027.
dc.identifier.citedreference	Joshi, A., Rienks, M., Theofilatos, K., & Mayr, M. ( 2021 ). Systems biology in cardiovascular disease: A multiomics approach. Nature Reviews Cardiology, 18 ( 5 ), 313 – 330.
dc.identifier.citedreference	Kaasik, A., Veksler, V., Boehm, E., Novotova, M., Minajeva, A., & Ventura-Clapier, R. ( 2001 ). Energetic crosstalk between organelles: Architectural integration of energy production and utilization. Circulation Research, 89 ( 2 ), 153 – 159.
dc.identifier.citedreference	Kadota, S., Pabon, L., Reinecke, H., & Murry, C. E. ( 2017 ). In vivo maturation of human induced pluripotent stem cell-derived cardiomyocytes in neonatal and adult rat hearts. Stem Cell Reports, 8 ( 2 ), 278 – 289.
dc.identifier.citedreference	Kanellakis, P., Ditiatkovski, M., Kostolias, G., & Bobik, A. ( 2012 ). A pro-fibrotic role for interleukin-4 in cardiac pressure overload. Cardiovascular Research, 95 ( 1 ), 77 – 85.
dc.identifier.citedreference	Kannan, S., & Kwon, C. ( 2020 ). Regulation of cardiomyocyte maturation during critical perinatal window. The Journal of Physiology, 598 ( 14 ), 2941 – 2956.
dc.identifier.citedreference	Kapela, A., Bezerianos, A., & Tsoukias, N. M. ( 2008 ). A mathematical model of Ca 2+ dynamics in rat mesenteric smooth muscle cell: Agonist and NO stimulation. Journal of Theoretical Biology, 253 ( 2 ), 238 – 260.
dc.identifier.citedreference	Kapela, A., Nagaraja, S., & Tsoukias, N. M. ( 2010 ). A mathematical model of vasoreactivity in rat mesenteric arterioles. II. Conducted vasoreactivity. American Journal of Physiology Heart and Circulatory Physiology, 298 ( 1 ), H52 – H65.
dc.identifier.citedreference	Karbassi, E., Fenix, A., Marchiano, S., Muraoka, N., Nakamura, K., Yang, X., & Murry, C. E. ( 2020 ). Cardiomyocyte maturation: Advances in knowledge and implications for regenerative medicine. Nature Reviews Cardiology, 17 ( 6 ), 341 – 359.
dc.identifier.citedreference	Karlin, A. ( 2015 ). Membrane potential and Ca 2+ concentration dependence on pressure and vasoactive agents in arterial smooth muscle: A model. Journal of General Physiology, 146 ( 1 ), 79 – 96.
dc.identifier.citedreference	Katchman, A., Yang, L., Zakharov, S. I., Kushner, J., Abrams, J., Chen, B. X., Liu, G., Pitt, G. S., Colecraft, H. M., & Marx, S. O. ( 2017 ). Proteolytic cleavage and PKA phosphorylation of alpha1C subunit are not required for adrenergic regulation of CaV1.2 in the heart. PNAS, 114 ( 34 ), 9194 – 9199.
dc.identifier.citedreference	Katz, D. H., Tahir, U. A., Bick, A. G., Pampana, A., Ngo, D., Benson, M. D., Yu, Z., Robbins, J. M., Chen, Z. Z., Cruz, D. E., Deng, S., Farrell, L., Sinha, S., Schmaier, A. A., Shen, D., Gao, Y., Hall, M. E., Correa, A., & Tracy, R. P., … Blood Institute TC ( 2022 ). Whole genome sequence analysis of the plasma proteome in black adults provides novel insights into cardiovascular disease. Circulation, 145 ( 5 ), 357 – 370.
dc.identifier.citedreference	Kedia-Mehta, N., & Finlay, D. K. ( 2019 ). Competition for nutrients and its role in controlling immune responses. Nature Communications, 10 ( 1 ), 2123.
dc.identifier.citedreference	Keef, K. D., Hume, J. R., & Zhong, J. ( 2001 ). Regulation of cardiac and smooth muscle Ca(2+) channels (Ca(V)1.2a,b) by protein kinases. American Journal of Physiology Cell Physiology, 281 ( 6 ), C1743 – C1756.
dc.identifier.citedreference	Keene, B. W., Atkins, C. E., Bonagura, J. D., Fox, P. R., Haggstrom, J., Fuentes, V. L., Oyama, M. A., Rush, J. E., Stepien, R., & Uechi, M. ( 2019 ). ACVIM consensus guidelines for the diagnosis and treatment of myxomatous mitral valve disease in dogs. Journal of Veterinary Internal Medicine, 33 ( 3 ), 1127 – 1140.
dc.identifier.citedreference	Kelly-Goss, M. R., Sweat, R. S., Stapor, P. C., Peirce, S. M., & Murfee, W. L. ( 2014 ). Targeting pericytes for angiogenic therapies. Microcirculation, 21 ( 4 ), 345 – 357.
dc.identifier.citedreference	Khalil, H., Kanisicak, O., Prasad, V., Correll, R. N., Fu, X., Schips, T., Vagnozzi, R. J., Liu, R., Huynh, T., Lee, S. J., Karch, J., & Molkentin, J. D. ( 2017 ). Fibroblast-specific TGF-beta-Smad2/3 signaling underlies cardiac fibrosis. Journal of Clinical Investigation, 127 ( 10 ), 3770 – 3783.
dc.identifier.citedreference	Kharche, S., Yu, J., Lei, M., & Zhang, H. ( 2011 ). A mathematical model of action potentials of mouse sinoatrial node cells with molecular bases. American Journal of Physiology Heart and Circulatory Physiology, 301 ( 3 ), H945 – H963.
dc.identifier.citedreference	Kim, D. H., Lipke, E. A., Kim, P., Cheong, R., Thompson, S., Delannoy, M., Suh, K. Y., Tung, L., & Levchenko, A. ( 2010 ). Nanoscale cues regulate the structure and function of macroscopic cardiac tissue constructs. PNAS, 107 ( 2 ), 565 – 570.
dc.identifier.citedreference	Kim, J. J., Yang, L., Lin, B., Zhu, X., Sun, B., Kaplan, A. D., Bett, G. C., Rasmusson, R. L., London, B., & Salama, G. ( 2015 ). Mechanism of automaticity in cardiomyocytes derived from human induced pluripotent stem cells. Journal of Molecular and Cellular Cardiology, 81, 81 – 93.
dc.identifier.citedreference	Kimura, W., Nakada, Y., & Sadek, H. A. ( 2017 ). Hypoxia-induced myocardial regeneration. Journal of Applied Physiology (1985), 123 ( 6 ), 1676 – 1681.
dc.identifier.citedreference	Kimura, W., Xiao, F., Canseco, D. C., Muralidhar, S., Thet, S., Zhang, H. M., Abderrahman, Y., Chen, R., Garcia, J. A., Shelton, J. M., Richardson, J. A., Ashour, A. M., Asaithamby, A., Liang, H., Xing, C., Lu, Z., Cheng Zhang, C., & Sadek, H. A. ( 2016 ). Corrigendum: Hypoxia fate mapping identifies cycling cardiomyocytes in the adult heart. Nature, 532 ( 7598 ), 268.
dc.identifier.citedreference	King, D. R., Sedovy, M. W., Eaton, X., Dunaway, L. S., Good, M. E., Isakson, B. E., & Johnstone, S. R. ( 2022 ). Cell-to-cell communication in the resistance vasculature. Comprehensive Physiology, 12, 1 – 35.
dc.identifier.citedreference	Kivela, R., Hemanthakumar, K. A., Vaparanta, K., Robciuc, M., Izumiya, Y., Kidoya, H., Takakura, N., Peng, X., Sawyer, D. B., Elenius, K., Walsh, K., & Alitalo, K. ( 2019 ). Endothelial cells regulate physiological cardiomyocyte growth via VEGFR2-mediated paracrine signaling. Circulation, 139 ( 22 ), 2570 – 2584.
dc.identifier.citedreference	Knaapen, P., Germans, T., Knuuti, J., Paulus, W. J., Dijkmans, P. A., Allaart, C. P., Lammertsma, A. A., & Visser, F. C. ( 2007 ). Myocardial energetics and efficiency: Current status of the noninvasive approach. Circulation, 115 ( 7 ), 918 – 927.
dc.identifier.citedreference	Knot, H. J., & Nelson, M. T. ( 1998 ). Regulation of arterial diameter and wall [Ca2+] in cerebral arteries of rat by membrane potential and intravascular pressure. The Journal of Physiology, 508 ( 1 ), 199 – 209.
dc.identifier.citedreference	Kolstad, T. R., van den Brink, J., MacQuaide, N., Lunde, P. K., Frisk, M., Aronsen, J. M., Norden, E. S., Cataliotti, A., Sjaastad, I., Sejersted, O. M., Edwards, A. G., Lines, G. T., & Louch, W. E. ( 2018 ). Ryanodine receptor dispersion disrupts Ca(2+) release in failing cardiac myocytes. Elife, 7.
dc.identifier.citedreference	Kucera, J. P., Rohr, S., & Rudy, Y. ( 2002 ). Localization of sodium channels in intercalated disks modulates cardiac conduction. Circulation Research, 91 ( 12 ), 1176 – 1182.
dc.identifier.citedreference	Kupfer, M. E., Lin, W. H., Ravikumar, V., Qiu, K., Wang, L., Gao, L., Bhuiyan, D. B., Lenz, M., Ai, J., Mahutga, R. R., Townsend, D., Zhang, J., McAlpine, M. C., Tolkacheva, E. G., & Ogle, B. M. ( 2020 ). In situ expansion, differentiation, and electromechanical coupling of human cardiac muscle in a 3D bioprinted, chambered organoid. Circulation Research, 127 ( 2 ), 207 – 224.
dc.identifier.citedreference	Kuppe, C., Ramirez Flores, R. O., Li, Z., Hayat, S., Levinson, R. T., Liao, X., Hannani, M. T., Tanevski, J., Wunnemann, F., Nagai, J. S., Halder, M., Schumacher, D., Menzel, S., Schafer, G., Hoeft, K., Cheng, M., Ziegler, S., Zhang, X., Peisker, F., … Kramann, R. ( 2022 ). Spatial multi-omic map of human myocardial infarction. Nature, 608 ( 7924 ), 766 – 777.
dc.identifier.citedreference	Lacoste, B., Comin, C. H., Ben-Zvi, A., Kaeser, P. S., Xu, X., Costa Lda, F., & Gu, C. ( 2014 ). Sensory-related neural activity regulates the structure of vascular networks in the cerebral cortex. Neuron, 83 ( 5 ), 1117 – 1130.
dc.identifier.citedreference	Lakatta, E. G., & DiFrancesco, D. ( 2009 ). What keeps us ticking: A funny current, a calcium clock, or both? Journal of Molecular and Cellular Cardiology, 47 ( 2 ), 157 – 170.
dc.identifier.citedreference	Langfelder, P., & Horvath, S. ( 2008 ). WGCNA: An R package for weighted correlation network analysis. BMC Bioinformatics [Electronic Resource], 9 ( 1 ), 559.
dc.identifier.citedreference	Lazzerini, P. E., Laghi-Pasini, F., Boutjdir, M., & Capecchi, P. L. ( 2022 ). Inflammatory cytokines and cardiac arrhythmias: The lesson from COVID-19. Nature Reviews Immunology, 22, 270 – 272.
dc.identifier.citedreference	Lehnart, S. E., & Wehrens, X. H. T. ( 2022 ). The role of junctophilin proteins in cellular function. Physiological Reviews, 102 ( 3 ), 1211 – 1261.
dc.identifier.citedreference	Lei, C. L., Wang, K., Clerx, M., Johnstone, R. H., Hortigon-Vinagre, M. P., Zamora, V., Allan, A., Smith, G. L., Gavaghan, D. J., Mirams, G. R., & Polonchuk, L. ( 2017 ). Tailoring mathematical models to stem-cell derived cardiomyocyte lines can improve predictions of drug-induced changes to their electrophysiology. Frontiers in Physiology, 8, 986.
dc.identifier.citedreference	Lemke, T., Welling, A., Christel, C. J., Blaich, A., Bernhard, D., Lenhardt, P., Hofmann, F., & Moosmang, S. ( 2008 ). Unchanged beta-adrenergic stimulation of cardiac L-type calcium channels in Ca v 1.2 phosphorylation site S1928A mutant mice. Journal of Biological Chemistry, 283 ( 50 ), 34738 – 34744.
dc.identifier.citedreference	Lendahl, U., Muhl, L., & Betsholtz, C. ( 2022 ). Identification, discrimination and heterogeneity of fibroblasts. Nature Communications, 13 ( 1 ), 3409.
dc.identifier.citedreference	Leo, M. D., & Jaggar, J. H. ( 2016 ). Ion channel trafficking and control of arterial contractility. In Levitan PI & Dopico M, Vascular ion channels in physiology and disease, ed. Springer International Publishing, pp. 153 – 168.
dc.identifier.citedreference	Leo-Macias, A., Agullo-Pascual, E., Sanchez-Alonso, J. L., Keegan, S., Lin, X., Arcos, T., Feng Xia, L., Korchev, Y. E., Gorelik, J., Fenyo, D., Rothenberg, E., Rothenberg, E., & Delmar, M. ( 2016 ). Nanoscale visualization of functional adhesion/excitability nodes at the intercalated disc. Nature Communications, 7 ( 1 ), 10342.
dc.identifier.citedreference	Leon-Mimila, P., Wang, J., & Huertas-Vazquez, A. ( 2019 ). Relevance of multi-omics studies in cardiovascular diseases. Frontiers in Cardiovascular Medicine, 6, 91.
dc.identifier.citedreference	Lerman, L. O., Kurtz, T. W., Touyz, R. M., Ellison, D. H., Chade, A. R., Crowley, S. D., Mattson, D. L., Mullins, J. J., Osborn, J., Eirin, A., Reckelhoff, J. F., Iadecola, C., & Coffman, T. M. ( 2019 ). Animal models of hypertension: A scientific statement from the American heart association. Hypertension, 73 ( 6 ), e87 – e120.
dc.identifier.citedreference	Louch, W. E., Perdreau-Dahl, H., & Edwards, A. G. ( 2022 ). Image-driven modeling of nanoscopic cardiac function: Where have we come from, and where are we going? Frontiers in Physiology, 13, 834211.
dc.identifier.citedreference	Lerner, E., Barth, A., Hendrix, J., Ambrose, B., Birkedal, V., Blanchard, S. C., Borner, R., Sung Chung, H., Cordes, T., Craggs, T. D., Deniz, A. A., Diao, J., Fei, J., Gonzalez, R. L., Gopich, I. V., Ha, T., Hanke, C. A., Haran, G., Hatzakis, N. S., … Weiss, S. ( 2021 ). FRET-based dynamic structural biology: Challenges, perspectives and an appeal for open-science practices. Elife, 10.
dc.identifier.citedreference	Lesnefsky, E. J., Chen, Q., & Hoppel, C. L. ( 2016 ). Mitochondrial metabolism in aging heart. Circulation Research, 118 ( 10 ), 1593 – 1611.
dc.identifier.citedreference	Levet, F., Hosy, E., Kechkar, A., Butler, C., Beghin, A., Choquet, D., & Sibarita, J. B. ( 2015 ). SR-Tesseler: A method to segment and quantify localization-based super-resolution microscopy data. Nature Methods, 12 ( 11 ), 1065 – 1071.
dc.identifier.citedreference	Levine, H. J. ( 1997 ). Rest heart rate and life expectancy. Journal of the American College of Cardiology, 30, 1104 – 1106.
dc.identifier.citedreference	Li, D., Melnyk, P., Feng, J., Wang, Z., Petrecca, K., Shrier, A., & Nattel, S. ( 2000 ). Effects of experimental heart failure on atrial cellular and ionic electrophysiology. Circulation, 101 ( 22 ), 2631 – 2638.
dc.identifier.citedreference	Li, F., Wang, X., Capasso, J. M., & Gerdes, A. M. ( 1996 ). Rapid transition of cardiac myocytes from hyperplasia to hypertrophy during postnatal development. Journal of Molecular and Cellular Cardiology, 28 ( 8 ), 1737 – 1746.
dc.identifier.citedreference	Li, N., Liu, J. Y., Qiu, H., Harris, T. R., Sirish, P., Hammock, B. D., & Chiamvimonvat, N. ( 2011 ). Use of metabolomic profiling in the study of arachidonic acid metabolism in cardiovascular disease. Congestive Heart Failure (Greenwich, Conn), 17 ( 1 ), 42 – 46.
dc.identifier.citedreference	Li, P., Liu, B., Wu, X., Lu, Y., Qiu, M., Shen, Y., Tian, Y., Liu, C., Chen, X., Yang, C., Deng, M., Wang, Y., Gu, J., Su, Z., Chen, X., Zhao, K., Sheng, Y., Zhang, S., Sun, W., & Kong, X. ( 2022 ). Perirenal adipose afferent nerves sustain pathological high blood pressure in rats. Nature Communications, 13 ( 1 ), 3130.
dc.identifier.citedreference	Liao, Z., Lockhead, D., Larson, E. D., & Proenza, C. ( 2010 ). Phosphorylation and modulation of hyperpolarization-activated HCN4 channels by protein kinase A in the mouse sinoatrial node. Journal of General Physiology, 136 ( 3 ), 247 – 258.
dc.identifier.citedreference	Lim, S. L., Lam, C. S., Segers, V. F., Brutsaert, D. L., & De Keulenaer, G. W. ( 2015 ). Cardiac endothelium-myocyte interaction: Clinical opportunities for new heart failure therapies regardless of ejection fraction. European Heart Journal, 36 ( 31 ), 2050 – 2060.
dc.identifier.citedreference	Lin, J., & Keener, J. P. ( 2010 ). Modeling electrical activity of myocardial cells incorporating the effects of ephaptic coupling. PNAS, 107 ( 49 ), 20935 – 20940.
dc.identifier.citedreference	Lindsey, M. L., Mayr, M., Gomes, A. V., Delles, C., Arrell, D. K., Murphy, A. M., Lange, R. A., Costello, C. E., Jin, Y. F., Laskowitz, D. T., Sam, F., Terzic, A., Van Eyk, J., Srinivas, P. R., American Heart Association Council on Functional G, Translational Biology CoCDitYCoCCCoC, Stroke Nursing CoH, & Stroke, C. ( 2015 ). Transformative impact of proteomics on cardiovascular health and disease: A scientific statement from the American heart association. Circulation, 132 ( 9 ), 852 – 872.
dc.identifier.citedreference	Lipsett, D. B., Frisk, M., Aronsen, J. M., Nordén, E. S., Buonarati, O. R., Cataliotti, A., Hell, J. W., Sjaastad, I., Christensen, G., & Louch, W. E. ( 2019 ). Cardiomyocyte substructure reverts to an immature phenotype during heart failure. The Journal of Physiology, 597 ( 7 ), 1833 – 1853.
dc.identifier.citedreference	Litvinukova, M., Talavera-Lopez, C., Maatz, H., Reichart, D., Worth, C. L., Lindberg, E. L., Kanda, M., Polanski, K., Heinig, M., Lee, M., Nadelmann, E. R., Roberts, K., Tuck, L., Fasouli, E. S., DeLaughter, D. M., McDonough, B., Wakimoto, H., Gorham, J. M., Samari, S., … Teichmann, S. A. ( 2020 ). Cells of the adult human heart. Nature, 588 ( 7838 ), 466 – 472.
dc.identifier.citedreference	Liu, G., Papa, A., Katchman, A. N., Zakharov, S. I., Roybal, D., Hennessey, J. A., Kushner, J., Yang, L., Chen, B. X., Kushnir, A., Dangas, K., Gygi, S. P., Pitt, G. S., Colecraft, H. M., Ben-Johny, M., Kalocsay, M., & Marx, S. O. ( 2020 ). Mechanism of adrenergic CaV1.2 stimulation revealed by proximity proteomics. Nature, 577 ( 7792 ), 695 – 700.
dc.identifier.citedreference	Liu, Z., Jin, L., Chen, J., Fang, Q., Ablameyko, S., Yin, Z., & Xu, Y. ( 2021 ). A survey on applications of deep learning in microscopy image analysis. Computers in Biology and Medicine, 134, 104523.
dc.identifier.citedreference	Longden, T. A., Dabertrand, F., Koide, M., Gonzales, A. L., Tykocki, N. R., Brayden, J. E., Hill-Eubanks, D., & Nelson, M. T. ( 2017 ). Capillary K(+)-sensing initiates retrograde hyperpolarization to increase local cerebral blood flow. Nature Neuroscience, 20 ( 5 ), 717 – 726.
dc.identifier.citedreference	Longhurst, J. C., Tjen, A., & Fu, L. W. ( 2001 ). Cardiac sympathetic afferent activation provoked by myocardial ischemia and reperfusion. Mechanisms and reflexes. Annals of the New York Academy of Sciences, 940 ( 1 ), 74 – 95.
dc.identifier.citedreference	Lopaschuk, G. D., & Jaswal, J. S. ( 2010 ). Energy metabolic phenotype of the cardiomyocyte during development, differentiation, and postnatal maturation. Journal of Cardiovascular Pharmacology, 56 ( 2 ), 130 – 140.
dc.identifier.citedreference	Lopaschuk, G. D., Karwi, Q. G., Tian, R., Wende, A. R., & Abel, E. D. ( 2021 ). Cardiac energy metabolism in heart failure. Circulation Research, 128 ( 10 ), 1487 – 1513.
dc.identifier.citedreference	Lopaschuk, G. D., & Ussher, J. R. ( 2016 ). Evolving concepts of myocardial energy metabolism: More than just fats and carbohydrates. Circulation Research, 119 ( 11 ), 1173 – 1176.
dc.identifier.citedreference	Louch, W. E., Koivumaki, J. T., & Tavi, P. ( 2015 ). Calcium signalling in developing cardiomyocytes: Implications for model systems and disease. The Journal of Physiology, 593 ( 5 ), 1047 – 1063.
dc.identifier.citedreference	Luis Fuentes, V., Abbott, J., Chetboul, V., Cote, E., Fox, P. R., Haggstrom, J., Kittleson, M. D., Schober, K., & Stern, J. A. ( 2020 ). ACVIM consensus statement guidelines for the classification, diagnosis, and management of cardiomyopathies in cats. Journal of Veterinary Internal Medicine, 34 ( 3 ), 1062 – 1077.
dc.identifier.citedreference	Lundy, S. D., Zhu, W. Z., Regnier, M., & Laflamme, M. A. ( 2013 ). Structural and functional maturation of cardiomyocytes derived from human pluripotent stem cells. Stem Cells and Development, 22 ( 14 ), 1991 – 2002.
dc.identifier.citedreference	Ly, C., & Weinberg, S. H. ( 2022 ). Automaticity in ventricular myocyte cell pairs with ephaptic and gap junction coupling. Chaos (Woodbury, NY), 32 ( 3 ), 033123.
dc.identifier.citedreference	MacCannell, K. A., Bazzazi, H., Chilton, L., Shibukawa, Y., Clark, R. B., & Giles, W. R. ( 2007 ). A mathematical model of electrotonic interactions between ventricular myocytes and fibroblasts. Biophysical Journal, 92 ( 11 ), 4121 – 4132.
dc.identifier.citedreference	MacQuaide, N., Tuan, H. T., Hotta, J., Sempels, W., Lenaerts, I., Holemans, P., Hofkens, J., Jafri, M. S., Willems, R., & Sipido, K. R. ( 2015 ). Ryanodine receptor cluster fragmentation and redistribution in persistent atrial fibrillation enhance calcium release. Cardiovascular Research, 108 ( 3 ), 387 – 398.
dc.identifier.citedreference	Maltsev, A. V., Maltsev, V. A., Mikheev, M., Maltseva, L. A., Sirenko, S. G., Lakatta, E. G., & Stern, M. D. ( 2011 ). Synchronization of stochastic Ca(2)(+) release units creates a rhythmic Ca(2)(+) clock in cardiac pacemaker cells. Biophysical Journal, 100 ( 2 ), 271 – 283.
dc.identifier.citedreference	Marin-Aragon, M., Flores-tamez, V. A., Hong, J., Reddy, G. R., Maillard, P., Burns, A. E., Man, K. N. M., Sasse, K. C., Ward, S. M., Catterall, W. A., Bers, D. M., Hell, J. W., Nieves-Cintron, M., & Navedo, M. F. ( 2022 ). Spatiotemporal Control of Vascular CaV1.2 by a1C S1928 Phosphorylation. Circulation Research, 131 ( 12 ), 1018 – 1033.
dc.identifier.citedreference	Martinez-Mateu, L., Saiz, J., & Aromolaran, A. S. ( 2019 ). Differential modulation of IK and ICa,L channels in high-fat diet-induced obese guinea pig atria. Frontiers in Physiology, 10, 1212.
dc.identifier.citedreference	Masuda, H., & Sperelakis, N. ( 1993 ). Inwardly rectifying potassium current in rat fetal and neonatal ventricular cardiomyocytes. American Journal of Physiology, 265, H1107 – H1111.
dc.identifier.citedreference	Matkovich, S. J., Zhang, Y., Van Booven, D. J., & Dorn, G. W., 2nd ( 2010 ). Deep mRNA sequencing for in vivo functional analysis of cardiac transcriptional regulators: application to Galphaq. Circulation Research, 106 ( 9 ), 1459 – 1467.
dc.identifier.citedreference	McGarrah, R. W., Crown, S. B., Zhang, G. F., Shah, S. H., & Newgard, C. B. ( 2018 ). Cardiovascular metabolomics. Circulation Research, 122 ( 9 ), 1238 – 1258.
dc.identifier.citedreference	Medvedev, R. Y., Sanchez-Alonso, J. L., Mansfield, C. A., Judina, A., Francis, A. J., Pagiatakis, C., Trayanova, N., Glukhov, A. V., Miragoli, M., Faggian, G., & Gorelik, J. ( 2021 ). Local hyperactivation of L-type Ca(2+) channels increases spontaneous Ca(2+) release activity and cellular hypertrophy in right ventricular myocytes from heart failure rats. Scientific Reports, 11 ( 1 ), 4840.
dc.identifier.citedreference	Melton, E., & Qiu, H. ( 2021 ). Interleukin-1beta in multifactorial hypertension: Inflammation, vascular smooth muscle cell and extracellular matrix remodeling, and non-coding RNA regulation. International Journal of Molecular Sciences, 22 ( 16 ), 8639.
dc.identifier.citedreference	Mezache, L., Struckman, H. L., Greer-Short, A., Hund, T. J., & Veeraraghavan, R. ( 2019 ). Indirect CLEM identifies proarrhythmic remodeling of intercalated disk nanodomains in murine atria following acute VEGF Treatment. Microscopy and Microanalysis, 25 ( S2 ), 1136 – 1137.
dc.identifier.citedreference	Michael, G., Xiao, L., Qi, X. Y., Dobrev, D., & Nattel, S. ( 2009 ). Remodelling of cardiac repolarization: How homeostatic responses can lead to arrhythmogenesis. Cardiovascular Research, 81 ( 3 ), 491 – 499.
dc.identifier.citedreference	Michelhaugh, S. A., & Januzzi, J. L., Jr ( 2020 ). Finding a needle in a haystack: Proteomics in heart failure. JACC Basic to Translational Science, 5 ( 10 ), 1043 – 1053.
dc.identifier.citedreference	Milstein, M. L., Musa, H., Balbuena, D. P., Anumonwo, J. M., Auerbach, D. S., Furspan, P. B., Hou, L., Hu, B., Schumacher, S. M., Vaidyanathan, R., Martens, J. R., & Jalife, J. ( 2012 ). Dynamic reciprocity of sodium and potassium channel expression in a macromolecular complex controls cardiac excitability and arrhythmia. PNAS, 109 ( 31 ), E2134 – E2143.
dc.identifier.citedreference	Mishra, S., & Kass, D. A. ( 2021 ). Cellular and molecular pathobiology of heart failure with preserved ejection fraction. Nature Reviews Cardiology, 18 ( 6 ), 400 – 423.
dc.identifier.citedreference	Moffitt, J. R., Lundberg, E., & Heyn, H. ( 2022 ). The emerging landscape of spatial profiling technologies. Nature Reviews Genetics, 23 ( 12 ), 741 – 759.
dc.identifier.citedreference	Moise, N., Struckman, H. L., Dagher, C., Veeraraghavan, R., & Weinberg, S. H. ( 2021 ). Intercalated disk nanoscale structure regulates cardiac conduction. Journal of General Physiology, 153 ( 8 ).
dc.identifier.citedreference	Mollova, M., Bersell, K., Walsh, S., Savla, J., Das, L. T., Park, S. Y., Silberstein, L. E., Dos Remedios, C. G., Graham, D., Colan, S., & Kuhn, B. ( 2013 ). Cardiomyocyte proliferation contributes to heart growth in young humans. PNAS, 110 ( 4 ), 1446 – 1451.
dc.identifier.citedreference	Moreno, C. M., Dixon, R. E., Tajada, S., Yuan, C., Opitz-Araya, X., Binder, M. D., & Santana, L. F. ( 2016 ). Ca(2+) entry into neurons is facilitated by cooperative gating of clustered CaV1.3 channels. Elife, 5.
dc.identifier.citedreference	Morgan, M. L., Brideau, C., Teo, W., Caprariello, A. V., & Stys, P. K. ( 2021 ). Label-free assessment of myelin status using birefringence microscopy. Journal of Neuroscience Methods, 360, 109226.
dc.identifier.citedreference	Morotti, S., Liu, C., Hegyi, B., Ni, H., Fogli Iseppe, A., Wang, L., Pritoni, M., Ripplinger, C. M., Bers, D. M., Edwards, A. G., & Grandi, E. ( 2021 ). Quantitative cross-species translators of cardiac myocyte electrophysiology: Model training, experimental validation, and applications. Science Advances, 7 ( 47 ), eabg0927.
dc.identifier.citedreference	Morotti, S., Nieves-Cintron, M., Nystoriak, M. A., Navedo, M. F., & Grandi, E. ( 2017 ). Predominant contribution of L-type Cav1.2 channel stimulation to impaired intracellular calcium and cerebral artery vasoconstriction in diabetic hyperglycemia. Channels (Austin), 11 ( 4 ), 340 – 346.
dc.identifier.citedreference	Morton, S. U., & Brodsky, D. ( 2016 ). Fetal physiology and the transition to extrauterine life. Clinics in Perinatology, 43 ( 3 ), 395 – 407.
dc.identifier.citedreference	Moshkforoush, A., Ashenagar, B., Harraz, O. F., Dabertrand, F., Longden, T. A., Nelson, M. T., & Tsoukias, N. M. ( 2020 ). The capillary Kir channel as sensor and amplifier of neuronal signals: Modeling insights on K(+)-mediated neurovascular communication. PNAS, 117 ( 28 ), 16626 – 16637.
dc.identifier.citedreference	Moskalik, A., Niderla-Bielinska, J., & Ratajska, A. ( 2022 ). Multiple roles of cardiac macrophages in heart homeostasis and failure. Heart Failure Reviews, 27 ( 4 ), 1413 – 1430.
dc.identifier.citedreference	Muhl, L., Genove, G., Leptidis, S., Liu, J., He, L., Mocci, G., Sun, Y., Gustafsson, S., Buyandelger, B., Chivukula, I. V., Segerstolpe, A., Raschperger, E., Hansson, E. M., Bjorkegren, J. L. M., Peng, X. R., Vanlandewijck, M., Lendahl, U., & Betsholtz, C. ( 2020 ). Single-cell analysis uncovers fibroblast heterogeneity and criteria for fibroblast and mural cell identification and discrimination. Nature Communications, 11 ( 1 ), 3953.
dc.identifier.citedreference	Mummery, C., Ward-van Oostwaard, D., Doevendans, P., Spijker, R., van den Brink, S., Hassink, R., van der Heyden, M., Opthof, T., Pera, M., de la Riviere, A. B., Passier, R., & Tertoolen, L. ( 2003 ). Differentiation of human embryonic stem cells to cardiomyocytes: Role of coculture with visceral endoderm-like cells. Circulation, 107 ( 21 ), 2733 – 2740.
dc.identifier.citedreference	Munro, M. L., van Hout, I., Aitken-Buck, H. M., Sugunesegran, R., Bhagwat, K., Davis, P. J., Lamberts, R. R., Coffey, S., Soeller, C., & Jones, P. P. ( 2021 ). Human atrial fibrillation is not associated with remodeling of ryanodine receptor clusters. Frontiers in Cell and Developmental Biology, 9, 633704.
dc.identifier.citedreference	Murakami, U., & Uchida, K. ( 1985 ). Contents of myofibrillar proteins in cardiac, skeletal, and smooth muscles. Journal of Biochemistry, 98 ( 1 ), 187 – 197.
dc.identifier.citedreference	Nakada, Y., Canseco, D. C., Thet, S., Abdisalaam, S., Asaithamby, A., Santos, C. X., Shah, A. M., Zhang, H., Faber, J. E., Kinter, M. T., Szweda, L. I., Xing, C., Hu, Z., Deberardinis, R. J., Schiattarella, G., Hill, J. A., Oz, O., Lu, Z., Zhang, C. C., … Sadek, H. A. ( 2017 ). Hypoxia induces heart regeneration in adult mice. Nature, 541 ( 7636 ), 222 – 227.
dc.identifier.citedreference	Nassal, D. M., Wan, X., Liu, H., Maleski, D., Ramirez-Navarro, A., Moravec, C. S., Ficker, E., Laurita, K. R., & Deschênes, I. ( 2017 ). KChIP2 is a core transcriptional regulator of cardiac excitability. Elife, 6.
dc.identifier.citedreference	Navedo, M. F., Cheng, E. P., Yuan, C., Votaw, S., Molkentin, J. D., Scott, J. D., & Santana, L. F. ( 2010 ). Increased coupled gating of L-type Ca2+ channels during hypertension and Timothy syndrome. Circulation Research, 106 ( 4 ), 748 – 756.
dc.identifier.citedreference	Navedo, M. F., Takeda, Y., Nieves-Cintron, M., Molkentin, J. D., & Santana, L. F. ( 2010 ). Elevated Ca2+ sparklet activity during acute hyperglycemia and diabetes in cerebral arterial smooth muscle cells. American journal of physiology Cell physiology, 298 ( 2 ), C211 - C220.
dc.identifier.citedreference	Neary, M. T., Ng, K. E., Ludtmann, M. H., Hall, A. R., Piotrowska, I., Ong, S. B., Hausenloy, D. J., Mohun, T. J., Abramov, A. Y., & Breckenridge, R. A. ( 2014 ). Hypoxia signaling controls postnatal changes in cardiac mitochondrial morphology and function. Journal of Molecular and Cellular Cardiology, 74, 340 – 352.
dc.identifier.citedreference	Newman, A. C., Nakatsu, M. N., Chou, W., Gershon, P. D., & Hughes, C. C. ( 2011 ). The requirement for fibroblasts in angiogenesis: Fibroblast-derived matrix proteins are essential for endothelial cell lumen formation. Molecular Biology of the Cell, 22 ( 20 ), 3791 – 3800.
dc.identifier.citedreference	Nguyen, H. Q., Chattoraj, S., Castillo, D., Nguyen, S. C., Nir, G., Lioutas, A., Hershberg, E. A., Martins, N. M. C., Reginato, P. L., Hannan, M., Beliveau, B. J., Church, G. M., Daugharthy, E. R., Marti-Renom, M. A., & Wu, C. T. ( 2020 ). 3D mapping and accelerated super-resolution imaging of the human genome using in situ sequencing. Nature Methods, 17 ( 8 ), 822 – 832.
dc.identifier.citedreference	Ni, H., Fogli Iseppe, A., Giles, W. R., Narayan, S. M., Zhang, H., Edwards, A. G., Morotti, S., & Grandi, E. ( 2020 ). Populations of in silico myocytes and tissues reveal synergy of multiatrial-predominant K(+) -current block in atrial fibrillation. British Journal of Pharmacology, 177, 4497 – 4515.
dc.identifier.citedreference	Ni, H., Morotti, S., & Grandi, E. ( 2018 ). A heart for diversity: Simulating variability in cardiac arrhythmia research. Frontiers in Physiology, 9, 958.
dc.identifier.citedreference	Nicolas-Avila, J. A., Lechuga-Vieco, A. V., Esteban-Martinez, L., Sanchez-Diaz, M., Diaz-Garcia, E., Santiago, D. J., Rubio-Ponce, A., Li, J. L., Balachander, A., Quintana, J. A., Martinez-de-Mena, R., Castejon-Vega, B., Pun-Garcia, A., Traves, P. G., Bonzon-Kulichenko, E., Garcia-Marques, F., Cusso, L., N, A. G., Gonzalez-Guerra, A., … Hidalgo, A. ( 2020 ). A network of macrophages supports mitochondrial homeostasis in the heart. Cell, 183 ( 1 ), 94 - 109.e23 e123.
dc.identifier.citedreference	Niederer, S. A., Lumens, J., & Trayanova, N. A. ( 2019 ). Computational models in cardiology. Nature Reviews Cardiology, 16 ( 2 ), 100 – 111.
dc.identifier.citedreference	Nielsen, S. H., Mouton, A. J., DeLeon-Pennell, K. Y., Genovese, F., Karsdal, M., & Lindsey, M. L. ( 2019 ). Understanding cardiac extracellular matrix remodeling to develop biomarkers of myocardial infarction outcomes. Matrix Biology, 75–76, 43 – 57.
dc.identifier.citedreference	Nieves-Cintron, M., Flores-Tamez, V. A., Le, T., Baudel, M. M., & Navedo, M. F. ( 2021 ). Cellular and molecular effects of hyperglycemia on ion channels in vascular smooth muscle. Cellular and Molecular Life Sciences, 78 ( 1 ), 31 – 61.
dc.identifier.citedreference	Nieves-Cintron, M., Nystoriak, M. A., Prada, M. P., Johnson, K., Fayer, W., Dell’Acqua, M. L., Scott, J. D., & Navedo, M. F. ( 2015 ). Selective downregulation of Kv2.1 function contributes to enhanced arterial tone during diabetes. Journal of Biological Chemistry, 290 ( 12 ), 7918 – 7929.
dc.identifier.citedreference	Nieves-Cintron, M., Syed, A. U., Nystoriak, M. A., & Navedo, M. F. ( 2018 ). Regulation of voltage-gated potassium channels in vascular smooth muscle during hypertension and metabolic disorders. Microcirculation, 25 ( 1 ), e12423.
dc.identifier.citedreference	Nir, G., Farabella, I., Perez Estrada, C., Ebeling, C. G., Beliveau, B. J., Sasaki, H. M., Lee, S. D., Nguyen, S. C., McCole, R. B., Chattoraj, S., Erceg, J., AlHaj Abed, J., Martins, N. M. C., Nguyen, H. Q., Hannan, M. A., Russell, S., Durand, N. C., Rao, S. S. P., Kishi, J. Y., … Wu, C. T. ( 2018 ). Walking along chromosomes with super-resolution imaging, contact maps, and integrative modeling. Plos Genetics, 14 ( 12 ), e1007872.
dc.identifier.citedreference	Nivala, M., & Qu, Z. ( 2012 ). Calcium alternans in a couplon network model of ventricular myocytes: Role of sarcoplasmic reticulum load. American Journal of Physiology Heart and Circulatory Physiology, 303 ( 3 ), H341 – H352.
dc.identifier.citedreference	Nivala, M., Song, Z., Weiss, J. N., & Qu, Z. ( 2015 ). T-tubule disruption promotes calcium alternans in failing ventricular myocytes: Mechanistic insights from computational modeling. Journal of Molecular and Cellular Cardiology, 79, 32 – 41.
dc.identifier.citedreference	Nowak, M. B., Poelzing, S., & Weinberg, S. H. ( 2021 ). Mechanisms underlying age-associated manifestation of cardiac sodium channel gain-of-function. Journal of Molecular and Cellular Cardiology, 153, 60 – 71.
dc.identifier.citedreference	Nowak, M. B., Veeraraghavan, R., Poelzing, S., & Weinberg, S. H. ( 2021 ). Cellular size, gap junctions, and sodium channel properties govern developmental changes in cardiac conduction. Frontiers in Physiology, 12, 731025.
dc.identifier.citedreference	Nurk, S., Koren, S., Rhie, A., Rautiainen, M., Bzikadze, A. V., Mikheenko, A., Vollger, M. R., Altemose, N., Uralsky, L., Gershman, A., Aganezov, S., Hoyt, S. J., Diekhans, M., Logsdon, G. A., Alonge, M., Antonarakis, S. E., Borchers, M., Bouffard, G. G., Brooks, S. Y., … Phillippy, A. M. ( 2022 ). The complete sequence of a human genome. Science, 376 ( 6588 ), 44 – 53.
dc.identifier.citedreference	Nystoriak, M. A., Nieves-Cintron, M., Nygren, P. J., Hinke, S. A., Nichols, C. B., Chen, C. Y., Puglisi, J. L., Izu, L. T., Bers, D. M., Dell’acqua, M. L., Scott, J. D., Santana, L. F., & Navedo, M. F. ( 2014 ). AKAP150 contributes to enhanced vascular tone by facilitating large-conductance Ca 2+ -activated K+ channel remodeling in hyperglycemia and diabetes mellitus. Circulation Research, 114 ( 4 ), 607 – 615.
dc.identifier.citedreference	Nystoriak, M. A., Nieves-Cintron, M., Patriarchi, T., Buonarati, O. R., Prada, M. P., Morotti, S., Grandi, E., Fernandes, J. D., Forbush, K., Hofmann, F., Sasse, K. C., Scott, J. D., Ward, S. M., Hell, J. W., & Navedo, M. F. ( 2017 ). Ser1928 phosphorylation by PKA stimulates the L-type Ca 2+ channel CaV1.2 and vasoconstriction during acute hyperglycemia and diabetes. Science Signaling, 10 ( 463 ).
dc.identifier.citedreference	O’Hara, R. P., Binka, E., Prakosa, A., Zimmerman, S. L., Cartoski, M. J., Abraham, M. R., Lu, D. Y., Boyle, P. M., & Trayanova, N. A. ( 2022 ). Personalized computational heart models with T1-mapped fibrotic remodeling predict sudden death risk in patients with hypertrophic cardiomyopathy. Elife, 11.
dc.identifier.citedreference	Ohanyan, V., Raph, S. M., Dwenger, M. M., Hu, X., Pucci, T., Mack, G., Moore, J. B.t, Chilian, W. M., Bhatnagar, A., & Nystoriak, M. A. ( 2021 ). Myocardial blood flow control by oxygen sensing vascular Kvbeta proteins. Circulation Research, 128 ( 6 ), 738 – 751.
dc.identifier.citedreference	Ojaghi, A., Carrazana, G., Caruso, C., Abbas, A., Myers, D. R., Lam, W. A., & Robles, F. E. ( 2020 ). Label-free hematology analysis using deep-ultraviolet microscopy. PNAS, 117 ( 26 ), 14779 – 14789.
dc.identifier.citedreference	Ongstad, E., & Kohl, P. ( 2016 ). Fibroblast-myocyte coupling in the heart: Potential relevance for therapeutic interventions. Journal of Molecular and Cellular Cardiology, 91, 238 – 246.
dc.identifier.citedreference	Opitz, C. A., Leake, M. C., Makarenko, I., Benes, V., & Linke, W. A. ( 2004 ). Developmentally regulated switching of titin size alters myofibrillar stiffness in the perinatal heart. Circulation Research, 94 ( 7 ), 967 – 975.
dc.identifier.citedreference	Parekh, A. B. ( 2016 ). Advances in intracellular Ca(2+) signalling. The Journal of Physiology, 594 ( 11 ), 2811 – 2812.
dc.identifier.citedreference	Parikh, S. S., Blackwell, D. J., Gomez-Hurtado, N., Frisk, M., Wang, L., Kim, K., Dahl, C. P., Fiane, A., Tonnessen, T., Kryshtal, D. O., Louch, W. E., & Knollmann, B. C. ( 2017 ). Thyroid and glucocorticoid hormones promote functional T-tubule development in human-induced pluripotent stem cell-derived cardiomyocytes. Circulation Research, 121 ( 12 ), 1323 – 1330.
dc.identifier.citedreference	Passini, E., Britton, O. J., Lu, H. R., Rohrbacher, J., Hermans, A. N., Gallacher, D. J., Greig, R. J. H., Bueno-Orovio, A., & Rodriguez, B. ( 2017 ). Human in silico drug trials demonstrate higher accuracy than animal models in predicting clinical pro-arrhythmic cardiotoxicity. Frontiers in Physiology, 8, 668.
dc.identifier.citedreference	Welsh, D. G., Morielli, A. D., Nelson, M. T., & Brayden, J. E. ( 2002 ). Transient receptor potential channels regulate myogenic tone of resistance arteries. Circulation Research, 90 ( 3 ), 248 – 250.
dc.identifier.citedreference	Patel, B., Bansal, S. S., Ismahil, M. A., Hamid, T., Rokosh, G., Mack, M., & Prabhu, S. D. ( 2018 ). CCR2(+) monocyte-derived infiltrating macrophages are required for adverse cardiac remodeling during pressure overload. JACC Basic to Translational Science, 3 ( 2 ), 230 – 244.
dc.identifier.citedreference	Pathmanathan, P., & Gray, R. A. ( 2018 ). Validation and trustworthiness of multiscale models of cardiac electrophysiology. Frontiers in Physiology, 9, 106.
dc.identifier.citedreference	Pellman, J., Zhang, J., & Sheikh, F. ( 2016 ). Myocyte-fibroblast communication in cardiac fibrosis and arrhythmias: Mechanisms and model systems. Journal of Molecular and Cellular Cardiology, 94, 22 – 31.
dc.identifier.citedreference	Peters, N. S., Severs, N. J., Rothery, S. M., Lincoln, C., Yacoub, M. H., & Green, C. R. ( 1994 ). Spatiotemporal relation between gap junctions and fascia adherens junctions during postnatal development of human ventricular myocardium. Circulation, 90 ( 2 ), 713 – 725.
dc.identifier.citedreference	Pianca, N., Di Bona, A., Lazzeri, E., Costantini, I., Franzoso, M., Prando, V., Armani, A., Rizzo, S., Fedrigo, M., Angelini, A., Basso, C., Pavone, F. S., Rubart, M., Sacconi, L., Zaglia, T., & Mongillo, M. ( 2019 ). Cardiac sympathetic innervation network shapes the myocardium by locally controlling cardiomyocyte size through the cellular proteolytic machinery. The Journal of Physiology, 597 ( 14 ), 3639 – 3656.
dc.identifier.citedreference	Pilz, P. M., Ward, J. E., Chang, W. T., Kiss, A., Bateh, E., Jha, A., Fisch, S., Podesser, B. K., & Liao, R. ( 2022 ). Large and small animal models of heart failure with reduced ejection fraction. Circulation Research, 130 ( 12 ), 1888 – 1905.
dc.identifier.citedreference	Pinto, A. R., Ilinykh, A., Ivey, M. J., Kuwabara, J. T., D’Antoni, M. L., Debuque, R., Chandran, A., Wang, L., Arora, K., Rosenthal, N. A., & Tallquist, M. D. ( 2016 ). Revisiting cardiac cellular composition. Circulation Research, 118, 400 – 409.
dc.identifier.citedreference	Pirruccello, J. P., Bick, A., Wang, M., Chaffin, M., Friedman, S., Yao, J., Guo, X., Venkatesh, B. A., Taylor, K. D., Post, W. S., Rich, S., Lima, J. A. C., Rotter, J. I., Philippakis, A., Lubitz, S. A., Ellinor, P. T., Khera, A. V., Kathiresan, S., & Aragam, K. G. ( 2020 ). Analysis of cardiac magnetic resonance imaging in 36,000 individuals yields genetic insights into dilated cardiomyopathy. Nature Communications, 11 ( 1 ), 2254.
dc.identifier.citedreference	Pirruccello, J. P., Di Achille, P., Nauffal, V., Nekoui, M., Friedman, S. F., Klarqvist, M. D. R., Chaffin, M. D., Weng, L. C., Cunningham, J. W., Khurshid, S., Roselli, C., Lin, H., Koyama, S., Ito, K., Kamatani, Y., Komuro, I., BioBank Japan, P., Jurgens, S. J., Benjamin, E. J., … Ellinor, P. T. ( 2022 ). Genetic analysis of right heart structure and function in 40,000 people. Nature Genetics, 54, 792 – 803.
dc.identifier.citedreference	Piskadlo, E., Eichenberger, B. T., Giorgetti, L., & Chao, J. A. ( 2022 ). Design, labeling, and application of probes for RNA smFISH. Methods in Molecular Biology, 2537, 173 – 183.
dc.identifier.citedreference	Poelzing, S., Weinberg, S. H., & Keener, J. P. ( 2021 ). Initiation and entrainment of multicellular automaticity via diffusion limited extracellular domains. Biophysical Journal, 120 ( 23 ), 5279 – 5294.
dc.identifier.citedreference	Pohjoismaki, J. L., Kruger, M., Al-Furoukh, N., Lagerstedt, A., Karhunen, P. J., & Braun, T. ( 2013 ). Postnatal cardiomyocyte growth and mitochondrial reorganization cause multiple changes in the proteome of human cardiomyocytes. Molecular Biosystems, 9 ( 6 ), 1210 – 1219.
dc.identifier.citedreference	Ponce-Balbuena, D., Guerrero-Serna, G., Valdivia, C. R., Caballero, R., Diez-Guerra, F. J., Jimenez-Vazquez, E. N., Ramirez, R. J., Monteiro da Rocha, A., Herron, T. J., Campbell, K. F., Willis, B. C., Alvarado, F. J., Zarzoso, M., Kaur, K., Perez-Hernandez, M., Matamoros, M., Valdivia, H. H., Delpon, E., & Jalife, J. ( 2018 ). Cardiac Kir2.1 and NaV1.5 channels traffic together to the sarcolemma to control excitability. Circulation Research, 122 ( 11 ), 1501 – 1516.
dc.identifier.citedreference	Prabhu, S. D., & Frangogiannis, N. G. ( 2016 ). The biological basis for cardiac repair after myocardial infarction: From inflammation to fibrosis. Circulation Research, 119 ( 1 ), 91 – 112.
dc.identifier.citedreference	Prada, M. P., Syed, A. U., Buonarati, O. R., Reddy, G. R., Nystoriak, M. A., Ghosh, D., Simo, S., Sato, D., Sasse, K. C., Ward, S. M., Santana, L. F., Xiang, Y. K., Hell, J. W., Nieves-Cintron, M., & Navedo, M. F. ( 2019 ). A Gs-coupled purinergic receptor boosts Ca(2+) influx and vascular contractility during diabetic hyperglycemia. Elife, 8.
dc.identifier.citedreference	Prada, M. P., Syed, A. U., Reddy, G. R., Martin-Aragon Baudel, M., Flores-Tamez, V. A., Sasse, K. C., Ward, S. M., Sirish, P., Chiamvimonvat, N., Bartels, P., Dickson, E. J., Hell, J. W., Scott, J. D., Santana, L. F., Xiang, Y. K., Navedo, M. F., & Nieves-Cintron, M. ( 2020 ). AKAP5 complex facilitates purinergic modulation of vascular L-type Ca(2+) channel CaV1.2. Nature Communications, 11 ( 1 ), 5303.
dc.identifier.citedreference	Prando, V., Da Broi, F., Franzoso, M., Plazzo, A. P., Pianca, N., Francolini, M., Basso, C., Kay, M. W., Zaglia, T., & Mongillo, M. ( 2018 ). Dynamics of neuroeffector coupling at cardiac sympathetic synapses. The Journal of Physiology, 596 ( 11 ), 2055 – 2075.
dc.identifier.citedreference	Pritchard, H. A. T., Pires, P. W., Yamasaki, E., Thakore, P., & Earley, S. ( 2018 ). Nanoscale remodeling of ryanodine receptor cluster size underlies cerebral microvascular dysfunction in Duchenne muscular dystrophy. PNAS, 115 ( 41 ), E9745 – E9752.
dc.identifier.citedreference	Prive, F. ( 2022 ). Using the UK Biobank as a global reference of worldwide populations: Application to measuring ancestry diversity from GWAS summary statistics. Bioinformatics, 38 ( 13 ), 3477 – 3480.
dc.identifier.citedreference	Sato, D., Dixon, R. E., Santana, L. F., & Navedo, M. F. ( 2018 ). A model for cooperative gating of L-type Ca2+ channels and its effects on cardiac alternans dynamics. Plos Computational Biology, 14 ( 1 ), e1005906.
dc.identifier.citedreference	Puente, B. N., Kimura, W., Muralidhar, S. A., Moon, J., Amatruda, J. F., Phelps, K. L., Grinsfelder, D., Rothermel, B. A., Chen, R., Garcia, J. A., Santos, C. X., Thet, S., Mori, E., Kinter, M. T., Rindler, P. M., Zacchigna, S., Mukherjee, S., Chen, D. J., Mahmoud, A. I., … Sadek, H. A. ( 2014 ). The oxygen-rich postnatal environment induces cardiomyocyte cell-cycle arrest through DNA damage response. Cell, 157 ( 3 ), 565 – 579.
dc.identifier.citedreference	Qu, Z., Nivala, M., & Weiss, J. N. ( 2013 ). Calcium alternans in cardiac myocytes: order from disorder. Journal of Molecular and Cellular Cardiology, 58, 100 – 109.
dc.identifier.citedreference	Rajan, A. M., Ma, R. C., Kocha, K. M., Zhang, D. J., & Huang, P. ( 2020 ). Dual function of perivascular fibroblasts in vascular stabilization in zebrafish. Plos Genetics, 16 ( 10 ), e1008800.
dc.identifier.citedreference	Rees, C. M., Yang, J. H., Santolini, M., Lusis, A. J., Weiss, J. N., & Karma, A. ( 2018 ). The Ca(2+) transient as a feedback sensor controlling cardiomyocyte ionic conductances in mouse populations. Elife, 7.
dc.identifier.citedreference	Reichart, D., Lindberg, E. L., Maatz, H., Miranda, A. M. A., Viveiros, A., Shvetsov, N., Gartner, A., Nadelmann, E. R., Lee, M., Kanemaru, K., Ruiz-Orera, J., Strohmenger, V., DeLaughter, D. M., Patone, G., Zhang, H., Woehler, A., Lippert, C., Kim, Y., Adami, E., … Seidman, C. E. ( 2022 ). Pathogenic variants damage cell composition and single cell transcription in cardiomyopathies. Science, 377 ( 6606 ), eabo1984.
dc.identifier.citedreference	Restrepo, J. G., Weiss, J. N., & Karma, A. ( 2008 ). Calsequestrin-mediated mechanism for cellular calcium transient alternans. Biophysical Journal, 95 ( 8 ), 3767 – 3789.
dc.identifier.citedreference	Riehle, C., & Bauersachs, J. ( 2019 ). Small animal models of heart failure. Cardiovascular Research, 115 ( 13 ), 1838 – 1849.
dc.identifier.citedreference	Ringer, S. ( 1883 ). A further contribution regarding the influence of the different constituents of the blood on the contraction of the heart. The Journal of Physiology, 4 ( 1 ), 29 – 42.3.
dc.identifier.citedreference	Roberts, B. N., Yang, P. C., Behrens, S. B., Moreno, J. D., & Clancy, C. E. ( 2012 ). Computational approaches to understand cardiac electrophysiology and arrhythmias. American Journal of Physiology Heart and Circulatory Physiology, 303 ( 7 ), H766 – H783.
dc.identifier.citedreference	Rog-Zielinska, E. A., Craig, M. A., Manning, J. R., Richardson, R. V., Gowans, G. J., Dunbar, D. R., Gharbi, K., Kenyon, C. J., Holmes, M. C., Hardie, D. G., Smith, G. L., & Chapman, K. E. ( 2015 ). Glucocorticoids promote structural and functional maturation of foetal cardiomyocytes: A role for PGC-1alpha. Cell Death and Differentiation, 22 ( 7 ), 1106 – 1116.
dc.identifier.citedreference	Roh, J., Hill, J. A., Singh, A., Valero-Munoz, M., & Sam, F. ( 2022 ). Heart failure with preserved ejection fraction: Heterogeneous syndrome, diverse preclinical models. Circulation Research, 130 ( 12 ), 1906 – 1925.
dc.identifier.citedreference	Rolfe, D. F., & Brown, G. C. ( 1997 ). Cellular energy utilization and molecular origin of standard metabolic rate in mammals. Physiological Reviews, 77 ( 3 ), 731 – 758.
dc.identifier.citedreference	Ronaldson-Bouchard, K., Ma, S. P., Yeager, K., Chen, T., Song, L., Sirabella, D., Morikawa, K., Teles, D., Yazawa, M., & Vunjak-Novakovic, G. ( 2018 ). Advanced maturation of human cardiac tissue grown from pluripotent stem cells. Nature, 556 ( 7700 ), 239 – 243.
dc.identifier.citedreference	Rosa-Garrido, M., Chapski, D. J., & Vondriska, T. M. ( 2018 ). Epigenomes in cardiovascular disease. Circulation Research, 122 ( 11 ), 1586 – 1607.
dc.identifier.citedreference	Rossler, K., Neuchrist, C., Kitz, K., Scheiner, O., Kraft, D., & Lassmann, H. ( 1992 ). Expression of leucocyte adhesion molecules at the human blood-brain barrier (BBB). Journal of Neuroscience Research, 31 ( 2 ), 365 – 374.
dc.identifier.citedreference	Rubenstein, D. S., & Lipsius, S. L. ( 1989 ). Mechanisms of automaticity in subsidiary pacemakers from cat right atrium. Circulation Research, 64 ( 4 ), 648 – 657.
dc.identifier.citedreference	Rudy, Y., & Silva, J. R. ( 2006 ). Computational biology in the study of cardiac ion channels and cell electrophysiology. Quarterly Reviews of Biophysics, 39 ( 1 ), 57 – 116.
dc.identifier.citedreference	Saks, V. A., Kaambre, T., Sikk, P., Eimre, M., Orlova, E., Paju, K., Piirsoo, A., Appaix, F., Kay, L., Regitz-Zagrosek, V., Fleck, E., & Seppet, E. ( 2001 ). Intracellular energetic units in red muscle cells. Biochemical Journal, 356 ( 2 ), 643 – 657.
dc.identifier.citedreference	Saljic, A., Grandi, E., & Dobrev, D. ( 2022 ). TGF-beta1-induced endothelial-mesenchymal transition: A potential contributor to fibrotic remodeling in atrial fibrillation? Journal of Clinical Investigation, 132 ( 13 ), e161070.
dc.identifier.citedreference	Sanchez-Alonso, J. L., Bhargava, A., O’Hara, T., Glukhov, A. V., Schobesberger, S., Bhogal, N., Sikkel, M. B., Mansfield, C., Korchev, Y. E., Lyon, A. R., Punjabi, P. P., Nikolaev, V. O., Trayanova, N. A., & Gorelik, J. ( 2016 ). Microdomain-specific modulation of L-type calcium channels leads to triggered ventricular arrhythmia in heart failure. Circulation Research, 119 ( 8 ), 944 – 955.
dc.identifier.citedreference	Sanchez-Alonso, J. L., Loucks, A., Schobesberger, S., van Cromvoirt, A. M., Poulet, C., Chowdhury, R. A., Trayanova, N., & Gorelik, J. ( 2020 ). Nanoscale regulation of L-type calcium channels differentiates between ischemic and dilated cardiomyopathies. EBioMedicine, 57, 102845.
dc.identifier.citedreference	Sarkar, A. X., & Sobie, E. A. ( 2011 ). Quantification of repolarization reserve to understand interpatient variability in the response to proarrhythmic drugs: A computational analysis. Heart Rhythm, 8 ( 11 ), 1749 – 1755.
dc.identifier.citedreference	Saucerman, J. J., Brunton, L. L., Michailova, A. P., & McCulloch, A. D. ( 2003 ). Modeling beta-adrenergic control of cardiac myocyte contractility in silico. Journal of Biological Chemistry, 278 ( 48 ), 47997 – 48003.
dc.identifier.citedreference	Savla, J. J., Levine, B. D., & Sadek, H. A. ( 2018 ). The effect of hypoxia on cardiovascular disease: Friend or foe? High Altitude Medicine & Biology, 19 ( 2 ), 124 – 130.
dc.identifier.citedreference	Savulescu, A. F., Brackin, R., Bouilhol, E., Dartigues, B., Warrell, J. H., Pimentel, M. R., Beaume, N., Fortunato, I. C., Dallongeville, S., Boulle, M., Soueidan, H., Agou, F., Schmoranzer, J., Olivo-Marin, J. C., Franco, C. A., Gomes, E. R., Nikolski, M., & Mhlanga, M. M. ( 2021 ). Interrogating RNA and protein spatial subcellular distribution in smFISH data with DypFISH. Cell Reports Methods, 1 ( 5 ), 100068.
dc.identifier.citedreference	Saxena, A., Chen, W., Su, Y., Rai, V., Uche, O. U., Li, N., & Frangogiannis, N. G. ( 2013 ). IL-1 induces proinflammatory leukocyte infiltration and regulates fibroblast phenotype in the infarcted myocardium. Journal of Immunology, 191 ( 9 ), 4838 – 4848.
dc.identifier.citedreference	Schiattarella, G. G., Alcaide, P., Condorelli, G., Gillette, T. G., Heymans, S., Jones, E. A. V., Kallikourdis, M., Lichtman, A., Marelli-Berg, F., Shah, S., Thorp, E. B., & Hill, J. A. ( 2022 ). Immunometabolic mechanisms of heart failure with preserved ejection fraction. Nature Cardiovascular Research, 1 ( 3 ), 211 – 222.
dc.identifier.citedreference	Schmidt, C., Wiedmann, F., Voigt, N., Zhou, X. B., Heijman, J., Lang, S., Albert, V., Kallenberger, S., Ruhparwar, A., Szabo, G., Kallenbach, K., Karck, M., Borggrefe, M., Biliczki, P., Ehrlich, J. R., Baczko, I., Lugenbiel, P., Schweizer, P. A., Donner, B. C., … Thomas, D. ( 2015 ). Upregulation of K(2P)3.1 K+ current causes action potential shortening in patients with chronic atrial fibrillation. Circulation, 132 ( 2 ), 82 – 92.
dc.identifier.citedreference	Schobesberger, S., Wright, P., Tokar, S., Bhargava, A., Mansfield, C., Glukhov, A. V., Poulet, C., Buzuk, A., Monszpart, A., Sikkel, M., Harding, S. E., Nikolaev, V. O., Lyon, A. R., & Gorelik, J. ( 2017 ). T-tubule remodelling disturbs localized beta2-adrenergic signalling in rat ventricular myocytes during the progression of heart failure. Cardiovascular Research, 113 ( 7 ), 770 – 782.
dc.identifier.citedreference	Seki, S., Nagashima, M., Yamada, Y., Tsutsuura, M., Kobayashi, T., Namiki, A., & Tohse, N. ( 2003 ). Fetal and postnatal development of Ca 2+ transients and Ca 2+ sparks in rat cardiomyocytes. Cardiovascular Research, 58 ( 3 ), 535 – 548.
dc.identifier.citedreference	Shannon, T. R., Wang, F., Puglisi, J., Weber, C., & Bers, D. M. ( 2004 ). A mathematical treatment of integrated Ca dynamics within the ventricular myocyte. Biophysical Journal, 87 ( 5 ), 3351 – 3371.
dc.identifier.citedreference	Sheard, T. M. D., Hurley, M. E., Colyer, J., White, E., Norman, R., Pervolaraki, E., Narayanasamy, K. K., Hou, Y., Kirton, H. M., Yang, Z., Hunter, L., Shim, J. U., Clowsley, A. H., Smith, A. J., Baddeley, D., Soeller, C., Colman, M. A., & Jayasinghe, I. ( 2019 ). Three-dimensional and chemical mapping of intracellular signaling nanodomains in health and disease with enhanced expansion microscopy. ACS Nano, 13, 2143 – 2157.
dc.identifier.citedreference	Shen, X., van den Brink, J., Bergan-Dahl, A., Kolstad, T. R., Norden, E. S., Hou, Y., Laasmaa, M., Aguilar-Sanchez, Y., Quick, A. P., Espe, E. K. S., Sjaastad, I., Wehrens, X. H. T., Edwards, A. G., Soeller, C., & Louch, W. E. ( 2022 ). Prolonged beta-adrenergic stimulation disperses ryanodine receptor clusters in cardiomyocytes and has implications for heart failure. Elife, 11.
dc.identifier.citedreference	Shiferaw, Y., Aistrup, G. L., Louch, W. E., & Wasserstrom, J. A. ( 2020 ). Remodeling promotes proarrhythmic disruption of calcium homeostasis in failing atrial myocytes. Biophysical Journal, 118 ( 2 ), 476 – 491.
dc.identifier.citedreference	Shiferaw, Y., Aistrup, G. L., & Wasserstrom, J. A. ( 2018 ). Synchronization of triggered waves in atrial tissue. Biophysical Journal, 115 ( 6 ), 1130 – 1141.
dc.identifier.citedreference	Shirai, T., Hilhorst, M., Harrison, D. G., Goronzy, J. J., & Weyand, C. M. ( 2015 ). Macrophages in vascular inflammation–From atherosclerosis to vasculitis. Autoimmunity, 48 ( 3 ), 139 – 151.
dc.identifier.citedreference	Shoemaker, J. K., Badrov, M. B., Al-Khazraji, B. K., & Jackson, D. N. ( 2015 ). Neural control of vascular function in skeletal muscle. Comprehensive Physiology, 6, 303 – 329.
dc.identifier.citedreference	Silva, H. S., Kapela, A., & Tsoukias, N. M. ( 2007 ). A mathematical model of plasma membrane electrophysiology and calcium dynamics in vascular endothelial cells. American Journal of Physiology Cell Physiology, 293 ( 1 ), C277 – C293.
dc.identifier.citedreference	Smirnov, D., Pikunov, A., Syunyaev, R., Deviatiiarov, R., Gusev, O., Aras, K., Gams, A., Koppel, A., & Efimov, I. R. ( 2020 ). Genetic algorithm-based personalized models of human cardiac action potential. PLoS One, 15 ( 5 ), e0231695.
dc.identifier.citedreference	Sobie, E. A., Dilly, K. W., dos Santos Cruz, J., Lederer, W. J., & Jafri, M. S. ( 2002 ). Termination of cardiac Ca(2+) sparks: An investigative mathematical model of calcium-induced calcium release. Biophysical Journal, 83 ( 1 ), 59 – 78.
dc.identifier.citedreference	Soltis, A. R., & Saucerman, J. J. ( 2010 ). Synergy between CaMKII substrates and beta-adrenergic signaling in regulation of cardiac myocyte Ca(2+) handling. Biophysical Journal, 99 ( 7 ), 2038 – 2047.
dc.identifier.citedreference	Song, Z., Liu, M. B., & Qu, Z. ( 2018 ). Transverse tubular network structures in the genesis of intracellular calcium alternans and triggered activity in cardiac cells. Journal of Molecular and Cellular Cardiology, 114, 288 – 299.
dc.identifier.citedreference	Soonpaa, M. H., & Field, L. J. ( 1998 ). Survey of studies examining mammalian cardiomyocyte DNA synthesis. Circulation Research, 83 ( 1 ), 15 – 26.
dc.identifier.citedreference	Sridhar, A., Nishijima, Y., Terentyev, D., Khan, M., Terentyeva, R., Hamlin, R. L., Nakayama, T., Gyorke, S., Cardounel, A. J., & Carnes, C. A. ( 2009 ). Chronic heart failure and the substrate for atrial fibrillation. Cardiovascular Research, 84 ( 2 ), 227 – 236.
dc.identifier.citedreference	Stapor, P. C., Sweat, R. S., Dashti, D. C., Betancourt, A. M., & Murfee, W. L. ( 2014 ). Pericyte dynamics during angiogenesis: New insights from new identities. Journal of Vascular Research, 51 ( 3 ), 163 – 174.
dc.identifier.citedreference	Stenmark, K. R., Yeager, M. E., El Kasmi, K. C., Nozik-Grayck, E., Gerasimovskaya, E. V., Li, M., Riddle, S. R., & Frid, M. G. ( 2013 ). The adventitia: Essential regulator of vascular wall structure and function. Annual Review of Physiology, 75 ( 1 ), 23 – 47.
dc.identifier.citedreference	Su, H., Cantrell, A. C., Zeng, H., Zhu, S. H., & Chen, J. X. ( 2021 ). Emerging role of pericytes and their secretome in the heart. Cells, 10 ( 3 ), 548.
dc.identifier.citedreference	Sun, Y., Timofeyev, V., Dennis, A., Bektik, E., Wan, X., Laurita, K. R., Deschenes, I., Li, R. A., & Fu, J. D. ( 2017 ). A singular role of IK1 promoting the development of cardiac automaticity during cardiomyocyte differentiation by IK1-induced activation of pacemaker current. Stem Cell Reviews and Reports, 13 ( 5 ), 631 – 643.
dc.identifier.citedreference	Swift, L. M., Burke, M., Guerrelli, D., Reilly, M., Ramadan, M., McCullough, D., Prudencio, T., Mulvany, C., Chaluvadi, A., Jaimes, R., & Posnack, N. G. ( 2020 ). Age-dependent changes in electrophysiology and calcium handling: Implications for pediatric cardiac research. American Journal of Physiology Heart and Circulatory Physiology, 318 ( 2 ), H354 – H365.
dc.identifier.citedreference	Swirski, F. K., & Nahrendorf, M. ( 2018 ). Cardioimmunology: The immune system in cardiac homeostasis and disease. Nature Reviews Immunology, 18 ( 12 ), 733 – 744.
dc.identifier.citedreference	Syed, A. U., Reddy, G. R., Ghosh, D., Prada, M. P., Nystoriak, M. A., Morotti, S., Grandi, E., Sirish, P., Chiamvimonvat, N., Hell, J. W., Santana, L. F., Xiang, Y. K., Nieves-Cintron, M., & Navedo, M. F. ( 2019 ). Adenylyl cyclase 5-generated cAMP controls cerebral vascular reactivity during diabetic hyperglycemia. Journal of Clinical Investigation, 129 ( 8 ), 3140 – 3152.
dc.identifier.citedreference	Tabassum, R., & Ripatti, S. ( 2021 ). Integrating lipidomics and genomics: Emerging tools to understand cardiovascular diseases. Cellular and Molecular Life Sciences, 78 ( 6 ), 2565 – 2584.
dc.identifier.citedreference	Talman, V., Teppo, J., Poho, P., Movahedi, P., Vaikkinen, A., Karhu, S. T., Trost, K., Suvitaival, T., Heikkonen, J., Pahikkala, T., Kotiaho, T., Kostiainen, R., Varjosalo, M., & Ruskoaho, H. ( 2018 ). Molecular atlas of postnatal mouse heart development. Journal of the American Heart Association, 7 ( 20 ), e010378.
dc.identifier.citedreference	Tan, C. M. J., Green, P., Tapoulal, N., Lewandowski, A. J., Leeson, P., & Herring, N. ( 2018 ). The role of neuropeptide Y in cardiovascular health and disease. Frontiers in Physiology, 9, 1281.
dc.identifier.citedreference	Tomek, J., Bueno-Orovio, A., Passini, E., Zhou, X., Minchole, A., Britton, O., Bartolucci, C., Severi, S., Shrier, A., Virag, L., Varro, A., & Rodriguez, B. ( 2019 ). Development, calibration, and validation of a novel human ventricular myocyte model in health, disease, and drug block. Elife, 8.
dc.identifier.citedreference	Torrente, A. G., Mesirca, P., Neco, P., Rizzetto, R., Dubel, S., Barrere, C., Sinegger-Brauns, M., Striessnig, J., Richard, S., Nargeot, J., Gomez, A. M., & Mangoni, M. E. ( 2016 ). L-type Cav1.3 channels regulate ryanodine receptor-dependent Ca 2+ release during sino-atrial node pacemaker activity. Cardiovascular Research, 109, 451 – 461.
dc.identifier.citedreference	Tripp, S., & Grueber, M. ( 2011 ). Economic Impact of the Human Genome Project.
dc.identifier.citedreference	Trost, A., Lange, S., Schroedl, F., Bruckner, D., Motloch, K. A., Bogner, B., Kaser-Eichberger, A., Strohmaier, C., Runge, C., Aigner, L., Rivera, F. J., & Reitsamer, H. A. ( 2016 ). Brain and retinal pericytes: Origin, function and role. Frontiers in Cellular Neuroscience, 10, 20.
dc.identifier.citedreference	Tsumoto, K., Ashihara, T., Naito, N., Shimamoto, T., Amano, A., Kurata, Y., & Kurachi, Y. ( 2020 ). Specific decreasing of Na(+) channel expression on the lateral membrane of cardiomyocytes causes fatal arrhythmias in Brugada syndrome. Scientific Reports, 10 ( 1 ), 19964.
dc.identifier.citedreference	Tykocki, N. R., Boerman, E. M., & Jackson, W. F. ( 2017 ). Smooth muscle ion channels and regulation of vascular tone in resistance arteries and arterioles. Comprehensive Physiology, 7, 485 – 581.
dc.identifier.citedreference	Vaidyanathan, R., Markandeya, Y. S., Kamp, T. J., Makielski, J. C., January, C. T., & Eckhardt, L. L. ( 2016 ). IK1-enhanced human-induced pluripotent stem cell-derived cardiomyocytes: An improved cardiomyocyte model to investigate inherited arrhythmia syndromes. American Journal of Physiology Heart and Circulatory Physiology, 310 ( 11 ), H1611 – H1621.
dc.identifier.citedreference	van den Boogaard, M., van Weerd, J. H., Bawazeer, A. C., Hooijkaas, I. B., van de Werken, H. J. G., Tessadori, F., de Laat, W., Barnett, P., Bakkers, J., & Christoffels, V. M. ( 2019 ). Identification and characterization of a transcribed distal enhancer involved in cardiac Kcnh2 regulation. Cell Reports, 28 ( 10 ), 2704 – 2714.e5 e2705.
dc.identifier.citedreference	van den Dries, K., Fransen, J., & Cambi, A. ( 2022 ). Fluorescence CLEM in biology: Historic developments and current super-resolution applications. Febs Letters, 596 ( 19 ), 2486 – 2496.
dc.identifier.citedreference	Varghese, A. ( 2016 ). Reciprocal modulation of I(K1)-I(Na) extends excitability in cardiac ventricular cells. Frontiers in Physiology, 7, 542.
dc.identifier.citedreference	Varshneya, M., Irurzun-Arana, I., Campana, C., Dariolli, R., Gutierrez, A., Pullinger, T. K., & Sobie, E. A. ( 2021 ). Investigational treatments for covid-19 may increase ventricular arrhythmia risk through drug interactions. CPT Pharmacometrics & Systems Pharmacology, 10 ( 2 ), 100 – 107.
dc.identifier.citedreference	Veeraraghavan, R., & Gourdie, R. G. ( 2016 ). Stochastic optical reconstruction microscopy-based relative localization analysis (STORM-RLA) for quantitative nanoscale assessment of spatial protein organization. Molecular Biology of the Cell, 27 ( 22 ), 3583 – 3590.
dc.identifier.citedreference	Veeraraghavan, R., Hoeker, G. S., Alvarez-Laviada, A., Hoagland, D., Wan, X., King, D. R., Sanchez-Alonso, J., Chen, C., Jourdan, J., Isom, L. L., Deschenes, I., Smyth, J. W., Gorelik, J., Poelzing, S., & Gourdie, R. G. ( 2018 ). The adhesion function of the sodium channel beta subunit (beta1) contributes to cardiac action potential propagation. Elife, 7.
dc.identifier.citedreference	Veeraraghavan, R., Lin, J., Hoeker, G. S., Keener, J. P., Gourdie, R. G., & Poelzing, S. ( 2015 ). Sodium channels in the Cx43 gap junction perinexus may constitute a cardiac ephapse: An experimental and modeling study. Pflugers Archiv: European Journal of Physiology, 467 ( 10 ), 2093 – 2105.
dc.identifier.citedreference	Veeraraghavan, R., Poelzing, S., & Gourdie, R. G. ( 2014a ). Intercellular electrical communication in the heart: A new, active role for the intercalated disk. Cell Communication & Adhesion, 21 ( 3 ), 161 – 167.
dc.identifier.citedreference	Veeraraghavan, R., Poelzing, S., & Gourdie, R. G. ( 2014b ). Old cogs, new tricks: A scaffolding role for connexin43 and a junctional role for sodium channels? Febs Letters, 588 ( 8 ), 1244 – 1248.
dc.identifier.citedreference	Velayutham, N., Alfieri, C. M., Agnew, E. J., Riggs, K. W., Baker, R. S., Ponny, S. R., Zafar, F., & Yutzey, K. E. ( 2020 ). Cardiomyocyte cell cycling, maturation, and growth by multinucleation in postnatal swine. Journal of Molecular and Cellular Cardiology, 146, 95 – 108.
dc.identifier.citedreference	Venter, J. C., Adams, M. D., Myers, E. W., Li, P. W., Mural, R. J., Sutton, G. G., Smith, H. O., Yandell, M., Evans, C. A., Holt, R. A., Gocayne, J. D., Amanatides, P., Ballew, R. M., Huson, D. H., Wortman, J. R., Zhang, Q., Kodira, C. D., Zheng, X. H., Chen, L., … Zhu, X. ( 2001 ). The sequence of the human genome. Science, 291 ( 5507 ), 1304 – 1351.
dc.identifier.citedreference	Vermij, S. H., Abriel, H., & van Veen, T. A. ( 2017 ). Refining the molecular organization of the cardiac intercalated disc. Cardiovascular Research, 113, 259 – 275.
dc.identifier.citedreference	Vicar, T., Balvan, J., Jaros, J., Jug, F., Kolar, R., Masarik, M., & Gumulec, J. ( 2019 ). Cell segmentation methods for label-free contrast microscopy: Review and comprehensive comparison. BMC Bioinformatics [Electronic Resource], 20 ( 1 ), 360.
dc.identifier.citedreference	Vinogradova, T. M., & Lakatta, E. G. ( 2009 ). Regulation of basal and reserve cardiac pacemaker function by interactions of cAMP-mediated PKA-dependent Ca2+ cycling with surface membrane channels. Journal of Molecular and Cellular Cardiology, 47 ( 4 ), 456 – 474.
dc.identifier.citedreference	Vreeker, A., van Stuijvenberg, L., Hund, T. J., Mohler, P. J., Nikkels, P. G., & van Veen, T. A. ( 2014 ). Assembly of the cardiac intercalated disk during pre- and postnatal development of the human heart. PLoS One, 9 ( 4 ), e94722.
dc.working.doi	NO	en
dc.owningcollname	Interdisciplinary and Peer-Reviewed

Files in this item

Name:: tjp15436_am.pdf
Size:: 3.108MB
Format:: PDF

View/Open

Name:: tjp15436-sup-0001-PeerReview.pdf
Size:: 279.7KB
Format:: PDF

View/Open

Name:: tjp15436.pdf
Size:: 3.369MB
Format:: PDF

View/Open

Interdisciplinary and Peer-Reviewed

Show simple item record

Remediation of Harmful Language

The University of Michigan Library aims to describe its collections in a way that respects the people and communities who create, use, and are represented in them. We encourage you to Contact Us anonymously if you encounter harmful or problematic language in catalog records or finding aids. More information about our policies and practices is available at Remediation of Harmful Language.

Accessibility

If you are unable to use this file in its current format, please select the Contact Us link and we can modify it to make it more accessible to you.